Altered brain sodium channel transcript levels in human epilepsy

Altered brain sodium channel transcript levels in human epilepsy

Normal, and perhaps pathological, characteristics of neuronal excitability are related to the distribution and density of voltage-gated ion channels such as the sodium channel. We studied normal and epileptic human brain using the ligase detection reaction to measure the relative quantities of mRNAs...

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Veröffentlicht in:Brain research. Molecular brain research. 1996, Vol.35 (1), p.84-90
Hauptverfasser: Lombardo, Anthony J., Kuzniecky, Ruben, Powers, Richard E., Brown, George B.
Format: Artikel
Sprache:eng
Schlagworte:
Adult
Analysis of Variance
Base Sequence
Biological and medical sciences
Brain - metabolism
DNA Primers
Epilepsy
Epilepsy - metabolism
Epilepsy - physiopathology
Epilepsy - surgery
Female
Frontal Lobe - metabolism
Frontal Lobe - pathology
Frontal Lobe - surgery
Headache. Facial pains. Syncopes. Epilepsia. Intracranial hypertension. Brain oedema. Cerebral palsy
Humans
Ion channel
Ligase detection reaction
Male
Medical sciences
Molecular Sequence Data
mRNA quantitation
Nervous system (semeiology, syndromes)
Neurology
Oligonucleotide Probes
Organ Specificity
Polymerase Chain Reaction
Pyramidal Cells - metabolism
Reference Values
RNA, Messenger - analysis
RNA, Messenger - biosynthesis
Sodium channel
Sodium Channels - biosynthesis
Sodium Channels - classification
Temporal Lobe - metabolism
Temporal Lobe - pathology
Temporal Lobe - surgery
Transcription, Genetic
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Beschreibung
Zusammenfassung:Normal, and perhaps pathological, characteristics of neuronal excitability are related to the distribution and density of voltage-gated ion channels such as the sodium channel. We studied normal and epileptic human brain using the ligase detection reaction to measure the relative quantities of mRNAs encoding sodium channel subtypes 1 and 2. Normal brains exhibited characteristic 1:2 ratios which varied by brain region, but the ratios were invariate among individuals. These normal values were altered as much as threefold in anatomically corresponding regions of epileptic brain tissues. Changes of this magnitude in such a highly conserved value support a potential role for sodium channels in the pathophysiology of epilepsy.
ISSN:0169-328X
1872-6941
DOI:10.1016/0169-328X(95)00194-W