Department of Physiology, University of Tennessee Health Science Center, Memphis, TN 38163, USA.
Am J Physiol Heart Circ Physiol. 2011 Nov;301(5):H1819-27. doi: 10.1152/ajpheart.00404.2011. Epub 2011 Aug 19.
Transmembrane protein (TMEM)16A channels are recently discovered membrane proteins that display electrophysiological properties similar to classic Ca(2+)-activated Cl(-) (Cl(Ca)) channels in native cells. The molecular identity of proteins that generate Cl(Ca) currents in smooth muscle cells (SMCs) of resistance-size arteries is unclear. Similarly, whether cerebral artery SMCs generate Cl(Ca) currents is controversial. Here, using molecular biology and patch-clamp electrophysiology, we examined TMEM16A channel expression and characterized Cl(-) currents in arterial SMCs of resistance-size rat cerebral arteries. RT-PCR amplified transcripts for TMEM16A but not TMEM16B-TMEM16H, TMEM16J, or TMEM16K family members in isolated pure cerebral artery SMCs. Western blot analysis using an antibody that recognized recombinant (r)TMEM16A channels detected TMEM16A protein in cerebral artery lysates. Arterial surface biotinylation and immunofluorescence indicated that TMEM16A channels are located primarily within the arterial SMC plasma membrane. Whole cell Cl(Ca) currents in arterial SMCs displayed properties similar to those generated by rTMEM16A channels, including Ca(2+) dependence, current-voltage relationship linearization by an elevation in intracellular Ca(2+) concentration, a Nerstian shift in reversal potential induced by reducing the extracellular Cl(-) concentration, and a negative reversal potential shift when substituting extracellular I(-) for Cl(-). A pore-targeting TMEM16A antibody similarly inhibited both arterial SMC Cl(Ca) and rTMEM16A currents. TMEM16A knockdown using small interfering RNA also inhibited arterial SMC Cl(Ca) currents. In summary, these data indicate that TMEM16A channels are expressed, insert into the plasma membrane, and generate Cl(Ca) currents in cerebral artery SMCs.
跨膜蛋白 (TMEM)16A 通道是最近发现的膜蛋白,在天然细胞中表现出类似于经典的 Ca(2+)激活的 Cl(-) (Cl(Ca))通道的电生理特性。在阻力大小动脉的平滑肌细胞 (SMCs) 中产生 Cl(Ca)电流的蛋白质的分子身份尚不清楚。同样,脑动脉 SMC 是否产生 Cl(Ca)电流也存在争议。在这里,我们使用分子生物学和膜片钳电生理学研究了 TMEM16A 通道的表达,并对阻力大小大鼠脑动脉的动脉 SMC 中的 Cl(-)电流进行了特征描述。在分离的纯脑动脉 SMC 中,RT-PCR 扩增了 TMEM16A 的转录本,但未扩增 TMEM16B-TMEM16H、TMEM16J 或 TMEM16K 家族成员的转录本。使用识别重组 (r)TMEM16A 通道的抗体进行的 Western blot 分析检测到脑动脉裂解物中的 TMEM16A 蛋白。动脉表面生物素化和免疫荧光表明,TMEM16A 通道主要位于动脉 SMC 质膜内。动脉 SMC 中的全细胞 Cl(Ca)电流表现出与 rTMEM16A 通道产生的电流相似的特性,包括 Ca(2+)依赖性、细胞内 Ca(2+)浓度升高导致电流-电压关系线性化、降低细胞外 Cl(-)浓度诱导反转电位的 Nerst 移位以及用 I(-)取代 Cl(-)时反转电位的负移。靶向 TMEM16A 通道的抗体同样抑制了动脉 SMC 的 Cl(Ca)和 rTMEM16A 电流。使用小干扰 RNA 进行的 TMEM16A 敲低也抑制了动脉 SMC 的 Cl(Ca)电流。总之,这些数据表明 TMEM16A 通道在脑动脉 SMC 中表达、插入质膜并产生 Cl(Ca)电流。