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Na+/K+‐ATPase dysfunction, primary (mutation) or secondary (energy crisis, neurodegenerative disease) increases neuronal excitability in the brain. To evaluate the mechanisms underlying such increased excitability we studied mice carrying the D801N ...
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RISS 인기검색어
Mechanisms of increased hippocampal excitability in the Mashl+/− mouse model of Na+/K+‐ATPase dysfunction
한글로보기https://www.riss.kr/link?id=O119102930
- 저자
- 발행기관
- 학술지명
- 권호사항
-
발행연도
2018년
-
작성언어
-
-
Print ISSN
0013-9580
-
Online ISSN
1528-1167
-
등재정보
SCI;SCIE;SCOPUS
-
자료형태
학술저널
-
수록면
1455-1468 [※수록면이 p5 이하이면, Review, Columns, Editor's Note, Abstract 등일 경우가 있습니다.]
- 소장기관
-
구독기관
- 전북대학교 중앙도서관
- 성균관대학교 중앙학술정보관
- 부산대학교 중앙도서관
- 전남대학교 중앙도서관
- 제주대학교 중앙도서관
- 중앙대학교 서울캠퍼스 중앙도서관
- 인천대학교 학산도서관
- 숙명여자대학교 중앙도서관
- 서강대학교 로욜라중앙도서관
- 계명대학교 동산도서관
- 충남대학교 중앙도서관
- 한양대학교 백남학술정보관
- 이화여자대학교 중앙도서관
- 고려대학교 도서관
-
0
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0
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부가정보
다국어 초록 (Multilingual Abstract)
Na+/K+‐ATPase dysfunction, primary (mutation) or secondary (energy crisis, neurodegenerative disease) increases neuronal excitability in the brain. To evaluate the mechanisms underlying such increased excitability we studied mice carrying the D801N mutation, the most common mutation causing human disease, specifically alternating hemiplegia of childhood (AHC) including epilepsy. Because the gene is expressed in all neurons, particularly γ‐aminobutyric acid (GABA)ergic interneurons, we hypothesized that the pathophysiology would involve both pyramidal cells and interneurons and that fast‐spiking interneurons, which have increased firing rates, would be most vulnerable.
We performed extracellular recordings, as well as whole‐cell patch clamp recordings from pyramidal cells and interneurons, in the CA1 region on hippocampal slices. We also performed immunohistochemistry from hippocampal sections to count CA1 pyramidal cells as well as parvalbumin‐positive interneurons. In addition, we performed video—electroencephalography (EEG) recordings from the dorsal hippocampal CA1 region.
We observed that juvenile knock‐in mice carrying the above mutation reproduce the human phenotype of AHC. We then demonstrated in the CA1 region of these mice the following findings as compared to wild type: (1) Increased number of spikes evoked by electrical stimulation of Schaffer collaterals; (2) equalization by bicuculline of the number of spikes induced by Schaffer collateral stimulation; (3) reduced miniature, spontaneous, and evoked inhibitory postsynaptic currents, but no change in excitatory postsynaptic currents; (4) robust action potential frequency adaptation in response to depolarizing current injection in CA1 fast‐spiking interneurons; and (5) no change in the number of pyramidal cells, but reduced number of parvalbumin positive interneurons.
Our data indicate that, in our genetic model of Atp1α3 mutation, there is increased excitability and marked dysfunction in GABAergic inhibition. This supports the performance of further investigations to determine if selective expression of the mutation in GABAergic and or glutamatergic neurons is necessary and sufficient to result in the behavioral phenotype.
We performed extracellular recordings, as well as whole‐cell patch clamp recordings from pyramidal cells and interneurons, in the CA1 region on hippocampal slices. We also performed immunohistochemistry from hippocampal sections to count CA1 pyramidal cells as well as parvalbumin‐positive interneurons. In addition, we performed video—electroencephalography (EEG) recordings from the dorsal hippocampal CA1 region.
We observed that juvenile knock‐in mice carrying the above mutation reproduce the human phenotype of AHC. We then demonstrated in the CA1 region of these mice the following findings as compared to wild type: (1) Increased number of spikes evoked by electrical stimulation of Schaffer collaterals; (2) equalization by bicuculline of the number of spikes induced by Schaffer collateral stimulation; (3) reduced miniature, spontaneous, and evoked inhibitory postsynaptic currents, but no change in excitatory postsynaptic currents; (4) robust action potential frequency adaptation in response to depolarizing current injection in CA1 fast‐spiking interneurons; and (5) no change in the number of pyramidal cells, but reduced number of parvalbumin positive interneurons.
Our data indicate that, in our genetic model of Atp1α3 mutation, there is increased excitability and marked dysfunction in GABAergic inhibition. This supports the performance of further investigations to determine if selective expression of the mutation in GABAergic and or glutamatergic neurons is necessary and sufficient to result in the behavioral phenotype.
Na+/K+‐ATPase dysfunction, primary (mutation) or secondary (energy crisis, neurodegenerative disease) increases neuronal excitability in the brain. To evaluate the mechanisms underlying such increased excitability we studied mice carrying the D801N mutation, the most common mutation causing human disease, specifically alternating hemiplegia of childhood (AHC) including epilepsy. Because the gene is expressed in all neurons, particularly γ‐aminobutyric acid (GABA)ergic interneurons, we hypothesized that the pathophysiology would involve both pyramidal cells and interneurons and that fast‐spiking interneurons, which have increased firing rates, would be most vulnerable.
We performed extracellular recordings, as well as whole‐cell patch clamp recordings from pyramidal cells and interneurons, in the CA1 region on hippocampal slices. We also performed immunohistochemistry from hippocampal sections to count CA1 pyramidal cells as well as parvalbumin‐positive interneurons. In addition, we performed video—electroencephalography (EEG) recordings from the dorsal hippocampal CA1 region.
We observed that juvenile knock‐in mice carrying the above mutation reproduce the human phenotype of AHC. We then demonstrated in the CA1 region of these mice the following findings as compared to wild type: (1) Increased number of spikes evoked by electrical stimulation of Schaffer collaterals; (2) equalization by bicuculline of the number of spikes induced by Schaffer collateral stimulation; (3) reduced miniature, spontaneous, and evoked inhibitory postsynaptic currents, but no change in excitatory postsynaptic currents; (4) robust action potential frequency adaptation in response to depolarizing current injection in CA1 fast‐spiking interneurons; and (5) no change in the number of pyramidal cells, but reduced number of parvalbumin positive interneurons.
Our data indicate that, in our genetic model of Atp1α3 mutation, there is increased excitability and marked dysfunction in GABAergic inhibition. This supports the performance of further investigations to determine if selective expression of the mutation in GABAergic and or glutamatergic neurons is necessary and sufficient to result in the behavioral phenotype.
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