Brakemeier Susanne, Eichler Ines, Hopp Hartmut, Köhler Ralf, Hoyer Joachim
Department of Nephrology, Universitätsklinikum Benjamin Franklin, Hindenburgdamm 30, D-12200 Berlin, Germany.
Cardiovasc Res. 2002 Jan;53(1):209-18. doi: 10.1016/s0008-6363(01)00476-x.
Stretch-activated cation channels (SAC) have been suggested to act as endothelial mechanosensors for hemodynamic forces. Ca(2+) influx through SAC could induce an intracellular Ca(2+) signal stimulating Ca(2+)-dependent synthesis of vasodilators like NO, prostacyclin, or EDHF. In the present study we tested whether laminar shear stress (LSS) regulates SAC function.
Electrophysiological properties of SAC were investigated in human umbilical vein endothelial cells (HUVEC) subjected to defined levels of LSS in a flow-cone apparatus.
In HUVEC, we identified a Ca(2+) permeable SAC that was activated by membrane stretch. Single-channel current densities of SAC in cell-attached patches were significantly increased in HUVEC exposed to an LSS of 5 dyn/cm(2) for 4 h (1.15+/-0.17 SAC/patch) compared to HUVEC kept in stationary culture (0.46+/-0.07 SAC/patch). Exposure of HUVEC to a higher LSS of 15 dyn/cm(2) for 4 h induced similar up-regulation of SAC (1.27+/-0.21 SAC/patch). After 24 h exposure to LSS of 15 dyn/cm(2), single-channel current densities of SAC remained up-regulated (1.07+/-0.18 SAC/patch) compared to controls. In addition, stretch-sensitivity of SAC (channel activity NP(o) at -30 mmHg) significantly increased after 2 h of exposure to LSS of 5 and 15 dyn/cm(2) and remained up-regulated after 24 h. Inhibition of protein kinases and tyrosine kinases by H7 and genistein, respectively, prevented LSS-induced alteration of SAC function.
Single-channel current density and mechanosensitivity of SAC in HUVEC is up-regulated by LSS. Up-regulation of SAC function leads to enhanced mechanosensitive Ca(2+) influx, and represents a novel adaptive mechanism of the endothelium in the presence of altered hemodynamic forces.
拉伸激活阳离子通道(SAC)被认为可作为血流动力学力的内皮机械传感器。通过SAC的Ca(2+)内流可诱导细胞内Ca(2+)信号,刺激Ca(2+)依赖性血管舒张剂如一氧化氮(NO)、前列环素或内皮衍生超极化因子(EDHF)的合成。在本研究中,我们测试了层流切应力(LSS)是否调节SAC功能。
在流动锥装置中,对处于特定水平LSS的人脐静脉内皮细胞(HUVEC)进行SAC电生理特性研究。
在HUVEC中,我们鉴定出一种可被膜拉伸激活的Ca(2+)通透性SAC。与静态培养的HUVEC(0.46±0.07个SAC/膜片)相比,暴露于5达因/平方厘米LSS 4小时的HUVEC中,细胞贴附膜片中SAC的单通道电流密度显著增加(1.15±0.17个SAC/膜片)。将HUVEC暴露于15达因/平方厘米的更高LSS 4小时,可诱导SAC出现类似的上调(1.27±0.21个SAC/膜片)。暴露于15达因/平方厘米LSS 24小时后,与对照组相比,SAC的单通道电流密度仍保持上调(1.07±0.18个SAC/膜片)。此外,暴露于5和15达因/平方厘米LSS 2小时后,SAC的拉伸敏感性(-30 mmHg时的通道活性NP(o))显著增加,并在24小时后仍保持上调。分别用H7和染料木黄酮抑制蛋白激酶和酪氨酸激酶,可阻止LSS诱导的SAC功能改变。
LSS可上调HUVEC中SAC的单通道电流密度和机械敏感性。SAC功能的上调导致机械敏感Ca(2+)内流增强,代表了内皮在血流动力学力改变时的一种新型适应性机制。