Prat A G, Bertorello A M, Ausiello D A, Cantiello H F
Renal Unit, Massachusetts General Hospital, Charlestown 02129.
Am J Physiol. 1993 Jul;265(1 Pt 1):C224-33. doi: 10.1152/ajpcell.1993.265.1.C224.
We have recently demonstrated a novel role for "short" actin filaments, a distinct species of polymerized actin different from either monomeric (G-actin) or long actin filaments (F-actin), in the activation of epithelial Na+ channels. In the present study, the role of actin in the activation of apical Na+ channels by the adenosine 3',5'-cyclic monophosphate-dependent protein kinase A (PKA) was investigated by patch-clamp techniques in A6 epithelial cells. In excised inside-out patches, addition of deoxyribonuclease I, which prevents actin polymerization, inhibited Na+ channel activation mediated by PKA. Disruption of endogenous actin filament organization with cytochalasin D for at least 1 h prevented the PKA-mediated activation of Na+ channels but not activation following the addition of actin to the cytosolic side of the patch. To assess the role of PKA on actin filament organization, actin was used as a substrate for the specific phosphorylation by the PKA. Actin was phosphorylated by PKA with an equilibrium stoichiometry of 2:1 mol PO4-actin monomer. Actin was phosphorylated in its monomeric form, but only poorly once polymerized. Furthermore, phosphorylated actin reduced the rate of actin polymerization. Thus actin allowed to polymerize for at least 1 h in the presence of PKA and ATP to obtain phosphorylated actin filaments induced Na+ channel activity in excised inside-out patches, in contrast to actin polymerized either in the absence of PKA or in the presence of PKA plus a PKA inhibitor (nonphosphorylated actin filaments). This was also confirmed by using purified phosphorylated G-actin incubated in a polymerizing buffer for at least 1 h at 37 degrees C. These data suggest that the form of actin required for Na+ channel activation (i.e., "short" actin filaments) may be favored by the phosphorylation of G-actin and may thus mediate or facilitate the activation of Na+ channels by PKA.
我们最近证明了“短”肌动蛋白丝在激活上皮钠通道方面具有新作用,“短”肌动蛋白丝是一种不同于单体(G - 肌动蛋白)或长肌动蛋白丝(F - 肌动蛋白)的独特聚合肌动蛋白种类。在本研究中,采用膜片钳技术在A6上皮细胞中研究了肌动蛋白在3',5'-环磷酸腺苷依赖性蛋白激酶A(PKA)激活顶端钠通道中的作用。在切除的内向外膜片中,添加可阻止肌动蛋白聚合的脱氧核糖核酸酶I,抑制了PKA介导的钠通道激活。用细胞松弛素D破坏内源性肌动蛋白丝组织至少1小时可阻止PKA介导的钠通道激活,但在膜片胞质侧添加肌动蛋白后则不会阻止激活。为了评估PKA对肌动蛋白丝组织的作用,将肌动蛋白用作PKA特异性磷酸化的底物。PKA使肌动蛋白磷酸化,平衡化学计量比为2:1摩尔磷酸根/肌动蛋白单体。肌动蛋白以单体形式被磷酸化,但聚合后磷酸化程度很低。此外,磷酸化的肌动蛋白降低了肌动蛋白聚合的速率。因此,与在无PKA或有PKA加PKA抑制剂(非磷酸化肌动蛋白丝)的情况下聚合的肌动蛋白相比,在PKA和ATP存在下聚合至少1小时以获得磷酸化肌动蛋白丝的肌动蛋白,在切除的内向外膜片中可诱导钠通道活性。使用在聚合缓冲液中于37℃孵育至少1小时的纯化磷酸化G - 肌动蛋白也证实了这一点。这些数据表明,钠通道激活所需的肌动蛋白形式(即“短”肌动蛋白丝)可能因G - 肌动蛋白的磷酸化而更受青睐,因此可能介导或促进PKA对钠通道的激活。
