Basal sympathetic activity generated in neonatal mouse brainstem–spinal cord preparation requires T‐type calcium channel subunit α1H

The T‐type calcium channel (T‐channel) is a low‐voltage‐activated channel. Whether T‐channels are involved in sympathetic nerve discharge (SND), with subunits α1G and α1H differentially regulating SND genesis, was explored using in vitro brainstem–spinal cord–splanchnic sympathetic nerve preparation...

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Published in:Experimental physiology 2011-05, Vol.96 (5), p.486-494
Main Authors: Chen, Chien‐Chang, Fan, Yu‐Pei, Shin, Hee‐Sup, Su, Chun‐Kuei
Format: Article
Language:English
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Summary:The T‐type calcium channel (T‐channel) is a low‐voltage‐activated channel. Whether T‐channels are involved in sympathetic nerve discharge (SND), with subunits α1G and α1H differentially regulating SND genesis, was explored using in vitro brainstem–spinal cord–splanchnic sympathetic nerve preparations of wild‐type and genetically modified B6 mice. Applications of 10–80 μm NNC 55‐0396 to block T‐channels in wild‐type mice reduced SND in a concentration‐dependent manner. Amounts of SND were measured in units of signal‐to‐noise ratio for objective comparisons between mouse groups. Comparable amounts of SND were observed in wild‐type and α1G−/− mice. However, only ∼40% of the amount of SND of that in wild‐type or α1G−/− mice was observed in α1H−/− mice. Whether a diminished excitatory drive originating in the brainstem could explain a low SND in α1H−/− mice was evaluated by cervical cord transections. Isolated spinal cord preparations of mice with different genetic backgrounds produced comparable amounts of SND. Excitability of the spinal circuitry was further explored by bath applications of 5 mm glutamate. Glutamate applications produced a prominent SND rise in all mouse groups. The ratios of glutamate‐induced SND rise were similar between wild‐type and α1H−/− mice, but significantly higher in α1G−/− mice. Taken together, these results suggest that α1H in mouse brainstem is essential for the genesis of presympathetic drive, whereas α1G in mouse spinal cord is functionally inhibitory for SND genesis. We conclude that α1H and α1G T‐channel subunits may differentially regulate mouse SND genesis at different levels of the neuraxis.
ISSN:0958-0670
1469-445X
DOI:10.1113/expphysiol.2010.056085