Koch J P, Korbmacher C
Zentrum der Physiologie, Johann Wolfgang Goethe-Universität, Theodor Stern-Kai 7, D-60590 Frankfurt am Main, Germany.
J Membr Biol. 2000 Oct 1;177(3):231-42. doi: 10.1007/s002320010006.
It has previously been shown that osmotic cell shrinkage activates a nonselective cation (NSC) channel in M-1 mouse cortical collecting duct cells [54] and in a variety of other cell types [20]. In the present study we further characterized the shrinkage-activated NSC channel in M-1 cells and its mechanism of activation using whole-cell current recordings. Osmotic cell shrinkage induced by addition of 100 mm sucrose to the bath solution caused a 20-fold increase in whole-cell inward currents from -10.8 +/- 1.5 pA to -211 +/- 10.2 pA (n = 103). A similar response was observed when cell shrinkage was elicited using a hypo-osmotic pipette solution. This indicates that cell shrinkage and not extracellular osmolarity per se is the signal for current activation. Cation substitution experiments revealed that the activated channels discriminate poorly between monovalent cations with a selectivity sequence NH(4) (1.2) > or = Na(+) (1) approximately K(+) (0.9) approximately Li(+) (0.9). In contrast there was no measurable permeability for Ca(2+) or Ba(2+) and the cation-to-anion permeability ratio was about 14. The DPC-derivatives flufenamic acid, 4-methyl-DPC and DCDPC were the most effective blockers followed by LOE 908, while amiloride and bumetanide were ineffective. The putative channel activator maitotoxin had no effect. Current activation was dependent upon the presence of intracellular ATP and Mg(2+) and was inhibited by staurosporine (1 microm) and calphostin C (1 microm). Moreover, cytochalasin D (10 microm) and taxol (2 microm) reduced the current response to cell shrinkage. These findings suggest that the activation mechanism of the shrinkage-activated NSC channel involves protein kinase mediated phosphorylation steps and cytoskeletal elements.
先前的研究表明,渗透性细胞皱缩可激活M-1小鼠皮质集合管细胞[54]及多种其他细胞类型[20]中的非选择性阳离子(NSC)通道。在本研究中,我们使用全细胞电流记录进一步对M-1细胞中皱缩激活的NSC通道及其激活机制进行了表征。向浴液中添加100 mM蔗糖诱导的渗透性细胞皱缩使全细胞内向电流从-10.8±1.5 pA增加了20倍,达到-211±10.2 pA(n = 103)。当使用低渗移液器溶液引发细胞皱缩时,观察到类似的反应。这表明细胞皱缩而非细胞外渗透压本身是电流激活的信号。阳离子替代实验表明,激活的通道对单价阳离子的区分能力较差,选择性顺序为NH(4) (1.2) ≥ Na(+) (1) ≈ K(+) (0.9) ≈ Li(+) (0.9)。相比之下,Ca(2+)或Ba(2+)没有可测量的通透性,阳离子与阴离子的通透性比值约为14。DPC衍生物氟芬那酸、4-甲基-DPC和DCDPC是最有效的阻滞剂,其次是LOE 908,而氨氯地平和布美他尼无效。推测的通道激活剂 maitotoxin没有作用。电流激活依赖于细胞内ATP和Mg(2+)的存在,并受到星形孢菌素(1 μM)和钙磷蛋白C(1 μM)的抑制。此外,细胞松弛素D(10 μM)和紫杉醇(2 μM)降低了对细胞皱缩的电流反应。这些发现表明,皱缩激活的NSC通道的激活机制涉及蛋白激酶介导的磷酸化步骤和细胞骨架成分。