Itoh Hideki, Tsuji Keiko, Sakaguchi Tomoko, Nagaoka Iori, Oka Yuko, Nakazawa Yuko, Yao Takenori, Jo Hikari, Ashihara Takashi, Ito Makoto, Horie Minoru, Imoto Keiji
Department of Information Physiology, National Institute for Physiological Sciences, Myodaiji, Okazaki 444-8787, Japan.
Int J Cardiol. 2007 Oct 18;121(3):239-48. doi: 10.1016/j.ijcard.2007.02.007. Epub 2007 Apr 18.
Accelerated intermediate inactivation, which is caused by mutations in the cardiac voltage-gated sodium channel alpha-subunit gene (SCN5A), is one of the molecular mechanisms underlying Brugada syndrome. The N406S mutation associated with Brugada syndrome results in the accelerated intermediate inactivation, in addition to unique pharmacological characteristics.
Functional sodium channels were expressed transiently in HEK293 cells by transfecting equally the alpha- and beta-subunit plasmids (1 microg/ml) and the sodium current were measured in whole-cell mode of patch-clamp recording.
Since the N406S mutant channel has a greatly reduced use-dependent block of lidocaine, we took the advantage of the mutant channel to examine the effect of lidocaine on intermediate inactivation using wild-type (WT) and N406S mutant channels recombinantly expressed in HEK293 cells. Lidocaine (100 microM) slowed the recovery from the fast inactivation similarly for WT and N406S. On the other hand, whereas lidocaine slowed the recovery from the intermediate inactivation for WT, lidocaine accelerated the recovery for N406S. Activity-dependent loss of channel availability by repetitive 500-ms pulses was more strongly enhanced and accelerated by lidocaine for WT, but lidocaine exerted little effect on the N406S channel.
We demonstrate that lidocaine may suppress Brugada syndrome associated with the N406S mutation by preventing the sodium channel from accumulating in the intermediate inactivation state.
心脏电压门控钠通道α亚基基因(SCN5A)突变引起的加速性中间失活是布加综合征的分子机制之一。与布加综合征相关的N406S突变除了具有独特的药理学特征外,还导致加速性中间失活。
通过等量转染α亚基和β亚基质粒(1μg/ml),在HEK293细胞中瞬时表达功能性钠通道,并采用膜片钳记录的全细胞模式测量钠电流。
由于N406S突变通道对利多卡因的使用依赖性阻滞大大降低,我们利用该突变通道,通过在HEK293细胞中重组表达的野生型(WT)和N406S突变通道,研究利多卡因对中间失活的影响。利多卡因(100μM)使WT和N406S从快速失活中的恢复同样减慢。另一方面,虽然利多卡因使WT从中间失活中的恢复减慢,但却加速了N406S的恢复。对于WT,利多卡因通过500毫秒重复脉冲导致的通道可用性的活性依赖性丧失更强且更快,但利多卡因对N406S通道几乎没有影响。
我们证明,利多卡因可能通过防止钠通道在中间失活状态下蓄积,从而抑制与N406S突变相关的布加综合征。
