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Neural stem cell–specific ITPA deficiency causes neural depolarization and epilepsy
Yuichiro Koga, Daisuke Tsuchimoto, Yoshinori Hayashi, Nona Abolhassani, Yasuto Yoneshima, Kunihiko Sakumi, Hiroshi Nakanishi, Shinya Toyokuni, Yusaku Nakabeppu
Yuichiro Koga, Daisuke Tsuchimoto, Yoshinori Hayashi, Nona Abolhassani, Yasuto Yoneshima, Kunihiko Sakumi, Hiroshi Nakanishi, Shinya Toyokuni, Yusaku Nakabeppu
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Research Article Neuroscience

Neural stem cell–specific ITPA deficiency causes neural depolarization and epilepsy

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Abstract

Inosine triphosphate pyrophosphatase (ITPA) hydrolyzes inosine triphosphate (ITP) and other deaminated purine nucleotides to the corresponding nucleoside monophosphates. In humans, ITPA deficiency causes severe encephalopathy with epileptic seizure, microcephaly, and developmental retardation. In this study, we established neural stem cell–specific Itpa–conditional KO mice (Itpa-cKO mice) to clarify the effects of ITPA deficiency on the neural system. The Itpa-cKO mice showed growth retardation and died within 3 weeks of birth. We did not observe any microcephaly in the Itpa-cKO mice, although the female Itpa-cKO mice did show adrenal hypoplasia. The Itpa-cKO mice showed limb-clasping upon tail suspension and spontaneous and/or audiogenic seizure. Whole-cell patch-clamp recordings from entorhinal cortex neurons in brain slices revealed a depolarized resting membrane potential, increased firing, and frequent spontaneous miniature excitatory postsynaptic current and miniature inhibitory postsynaptic current in the Itpa-cKO mice compared with ITPA-proficient controls. Accumulated ITP or its metabolites, such as cyclic inosine monophosphates, or RNA containing inosines may cause membrane depolarization and hyperexcitability in neurons and induce the phenotype of ITPA-deficient mice, including seizure.

Authors

Yuichiro Koga, Daisuke Tsuchimoto, Yoshinori Hayashi, Nona Abolhassani, Yasuto Yoneshima, Kunihiko Sakumi, Hiroshi Nakanishi, Shinya Toyokuni, Yusaku Nakabeppu

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Figure 6

Electrophysiological properties of entorhinal cortex neurons of P15 to P18 male mice.

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Electrophysiological properties of entorhinal cortex neurons of P15 to P...
(A) Resting membrane potential (RMP). The RMP of entorhinal cortex neurons was analyzed by the whole-cell current-clamp test with sliced mouse brains and shown as box plots. Control cells (26 cells from 3 male control mice) and Itpa-cKO cells (24 cells from 3 male Itpa-cKO mice) were analyzed. Statistical analyses were performed with Wilcoxon’s rank sum test; ***P = 0.0005. (B) Action potential (AP) firing. AP firings of Itpa-cKO cells (21 cells from 3 Itpa-cKO male mice) and control cells (25 cells from 3 control male mice; Itpafl/fl) were detected with or without current injection. The current injection-dependent increase in the frequencies of AP firings is shown as the mean ± SD (right). Representative recordings of AP firing from control (upper) and Itpa-cKO (lower) brain slices are shown on the left. A 2-way repeated measures ANOVA using least square regression, Itpa-cKO vs. control ***P = 0.0008. (C) Miniature excitatory postsynaptic current (mEPSC). mEPSCs of Itpa-cKO cells (21 cells from 3 Itpa-cKO male mice) and control cells (24 cells from 3 control male mice) were analyzed by voltage-clamp recordings. Representative trace (left) and box plots of the frequency (middle) and amplitude (right) of mEPSCs are shown. Statistical analyses were performed with Wilcoxon’s rank sum test, frequency **P = 0.005, amplitude *P = 0.0209. (D) Miniature inhibitory postsynaptic current (mIPSC). mIPSCs of Itpa-cKO cells (23 cells from 3 Itpa-cKO male mice) and control cells (21 cells from 3 control male mice) were analyzed. Representative trace (left) and box plots of the frequency (middle) and amplitude (right) of mIPSCs are shown. Statistical analyses were performed with Wilcoxon’s rank sum test, frequency ****P < 0.0001, amplitude P = 0.7069.

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