Recurrent neonatal seizures increase tonic inhibition and respond to enhancers of δ-containing GABAA receptors
Gage T. Liddiard, Gordon F. Buchanan, Mark L. Schultz, Joseph Glykys
Gage T. Liddiard, Gordon F. Buchanan, Mark L. Schultz, Joseph Glykys
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Research Article Cell biology Neuroscience

Recurrent neonatal seizures increase tonic inhibition and respond to enhancers of δ-containing GABAA receptors

Abstract

About one-third of neonatal seizures do not respond to the first-line anticonvulsant phenobarbital, which activates phasic inhibition and whose effectiveness decreases over time. Whether enhancing tonic inhibition can treat refractory seizures or status epilepticus in neonates remains uncertain. We evaluated the effect of recurrent seizure-like events (SLE) on α5– and δ–GABAA receptor (α5- and δ-GABAAR) subunit expression and tonic inhibition in neonatal C57BL/6J mice (P6–9, both sexes) using acute brain slices. We investigated the impact of THIP (gaboxadol) on neonatal behavioral seizures, neuronal apoptosis, and neurodegeneration in vivo. We found neonatal neocortical expression of α5- and δ-GABAAR subunits. Blocking α5-GABAARs with L-655,708 did not affect acute neonatal SLE, whereas enhancing δ-GABAARs with THDOC, a neurosteroid, reduced them. The α5- and δ-GABAAR membrane expression increased after 8 hours of neonatal SLE and correlated with increased δ-mediated conductance but not α5-mediated conductance. Enhancing tonic inhibition was more effective in reducing recurrent neonatal SLE (8 hours) compared with early treatment. Increasing tonic inhibition reduced the duration, severity, and number of kainic acid–induced in vivo neonatal behavioral seizures without increasing neurodegeneration or apoptosis. We conclude that recurrent neonatal seizures increase tonic inhibition. Therefore, enhancing tonic inhibition may be a treatment strategy for prolonged neonatal status epilepticus.

Authors

Gage T. Liddiard, Gordon F. Buchanan, Mark L. Schultz, Joseph Glykys

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Figure 7

Enhancing tonic inhibition is more effective after recurrent neonatal seizure-like events.

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Enhancing tonic inhibition is more effective after recurrent neonatal se...
Top: Seizure-like events induced by Low-Mg2+ aCSF in the neocortex, layer IV/V (A), and CA1 stratum pyramidale (B) recorded with an extracellular field electrode in acute brain slices (P8). Below: FFT power area from top traces calculated every 30 seconds. The upper group was recorded with no prior Low-Mg2+ incubation, while the lower group was after 8 hours of incubation. (C) FFT power ratios versus seizure incubation duration in the neonatal neocortex and CA1 region. Linear regression, n = 37 neocortices (slope = –0.037), n = 41 CA1 regions (slope = –0.039). Dashed lines ± 95% CI. (D) THIP’s effect between slices at 0, 3, and after 8 hours in Low-Mg2+. Neocortex: 0 hours: 0.88 [0.75, 1.0], 3 hours: 0.68 [0.45, 0.92], 8 hours: 0.53 [0.34, 0.72]; 1-way ANOVA, F(2, 15) = 6.009, P = 0.012; n = 7, 6, 5 respectively. CA1 region: 0 hours: 0.91 [0.74, 1.08], 3 hours: 0.66 [0.45, 0.87], 8 hours: 0.57 [0.38, 0.76]; 1-way ANOVA, F(2, 17) = 4.604, P = 0.025, n = 7, 8, 5 respectively. (E) Diazepam’s (DZP) effect on slices after 8 hours in Low-Mg2+. Neocortex: 1.01 [0.98, 1.33], P = 0.88, 1-sample t test, n = 10; CA1 region: 1.05 [0.93, 1.17], P = 0.35, 1-sample t test, n = 10. (F) Number of SLE during THIP (y axis) versus baseline (x axis) in the pup neocortex and CA1 region at 0, 3, and 8 hours of Low-Mg2+. The line represents a slope of 1. Circles: individual slices. Black lines: mean ± 95% CI.