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钙通道电压依赖性α1A 亚基 R192Q 突变型小鼠睡眠减少和低腺苷能敏感性。

Reduced sleep and low adenosinergic sensitivity in cacna1a R192Q mutant mice.

机构信息

Laboratory for Neurophysiology, Department of Molecular Cell Biology, Leiden University Medical Center, Leiden, The Netherlands.

出版信息

Sleep. 2013 Jan 1;36(1):127-36. doi: 10.5665/sleep.2316.

DOI:10.5665/sleep.2316
PMID:23288979
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3524534/
Abstract

STUDY OBJECTIVES

Adenosine modulates sleep via A(1) and A(2A) receptors. As the A(1) receptor influences Ca(V)2.1 channel functioning via G-protein inhibition, there is a possible role of the Ca(V)2.1 channel in sleep regulation. To this end we investigated transgenic Cacna1a R192Q mutant mice that express mutant Ca(V)2.1 channels that are less susceptible to inhibition by G-proteins. We hypothesized that Cacna1a R192Q mice could show reduced susceptibility to adenosine, which may result in a sleep phenotype characterized by decreased sleep.

DESIGN

R192Q mutant and littermate wild-type mice were subjected to a 6-h sleep deprivation, treatment with caffeine (a non-specific adenosine receptor antagonist which induces waking), or cyclopentyladenosine (CPA, an A(1) receptor specific agonist which induces sleep).

MEASUREMENTS AND RESULTS

Under baseline conditions, Cacna1a R192Q mice showed more waking with longer waking episodes in the dark period and less non-rapid eye movement (NREM) sleep, but equal amounts of REM sleep compared to wild-type. After treatment with caffeine R192Q mice initiated sleep 30 min earlier than wild-type, whereas after CPA treatment, R192Q mice woke up 260 min earlier than wild-type. Both results indicate that Cacna1a R192Q mice are less susceptible to adenosinergic input, which may explain the larger amount of waking under undisturbed baseline conditions.

CONCLUSION

We here show that adenosinergic sleep induction, and responses to caffeine and CPA, are modified in the R192Q mutant in a manner consistent with decreased susceptibility to inhibition by adenosine. The data suggest that the A(1) receptor modulates sleep via the Ca(V)2.1 channel.

摘要

研究目的

腺苷通过 A(1) 和 A(2A) 受体来调节睡眠。由于 A(1) 受体通过 G 蛋白抑制影响 Ca(V)2.1 通道的功能,因此 Ca(V)2.1 通道在睡眠调节中可能具有作用。为此,我们研究了表达突变 Ca(V)2.1 通道的 Cacna1a R192Q 转基因突变体小鼠,这些突变通道对 G 蛋白的抑制作用的敏感性降低。我们假设 Cacna1a R192Q 小鼠可能对腺苷的敏感性降低,这可能导致以睡眠减少为特征的睡眠表型。

设计

R192Q 突变体和同窝野生型小鼠接受 6 小时的睡眠剥夺,并用咖啡因(一种非特异性腺苷受体拮抗剂,可诱导觉醒)或环戊基腺苷(CPA,一种 A(1) 受体特异性激动剂,可诱导睡眠)处理。

测量和结果

在基础条件下,Cacna1a R192Q 小鼠在黑暗期表现出更多的觉醒,觉醒期更长,非快速眼动(NREM)睡眠时间减少,但 REM 睡眠时间与野生型相同。用咖啡因处理后,R192Q 小鼠比野生型更早开始睡眠,而用 CPA 处理后,R192Q 小鼠比野生型早醒来 260 分钟。这两个结果都表明,Cacna1a R192Q 小鼠对腺苷能输入的敏感性降低,这可能解释了在未受干扰的基础条件下,它们的觉醒量更大的原因。

结论

我们在这里表明,R192Q 突变体的腺苷能诱导睡眠以及对咖啡因和 CPA 的反应,以与对腺苷抑制的敏感性降低一致的方式发生改变。数据表明,A(1) 受体通过 Ca(V)2.1 通道调节睡眠。

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