离子跨脉络丛转运的机制。
Mechanisms of ion transport across the choroid plexus.
作者信息
Wright E M
出版信息
J Physiol. 1972 Oct;226(2):545-71. doi: 10.1113/jphysiol.1972.sp009997.
Abstract
- Mechanisms of ion transport across the choroidal epithelium were investigated using an in vitro preparation of the frog choroid plexus.2. Sodium was actively transported across the plexus from the vascular to the ventricular surface by an ouabain sensitive electrically silent pump. As in other epithelial membranes the rate of sodium transport was stimulated by the presence of bicarbonate ions in the Ringer solutions. Chloride and bicarbonate ions accompany the net flux of sodium across this tissue.3. Some experiments suggest that potassium is actively transported from the ventricular to the serosal surface, and that the rate of transport is a function of the extracellular potassium concentration.4. No evidence was obtained to suggest that calcium is actively transported across this tissue in either direction.5. Diamox, ethoxyzolamide, pitocin, pitressin, hydrocortisone, amiloride, spironolactone and anoxia all failed to influence sodium transport.6. The sequence of passive ion permeation across the plexus was P(Rb) approximately P(K) > P(Cs) approximately P(Na) approximately P(Cl) approximately P(HCO3) > P(Li) as deduced from diffusion potential measurements. At least for Na, K and Cl there was a good correlation between the permeability coefficients derived from unidirectional flux measurements and from electrical parameters. This indicates that exchange diffusion is unimportant as a mechanism for passive ion transport.7. The instantaneous current-voltage curves were linear in both symmetrical and asymmetrical salt solutions and the choroid plexus conductance was found to be directly proportional to the external salt concentration. These and other lines of evidence suggest that the major route of passive ion permeation across this epithelium is via the tight junction route and not through the cell interior.8. These results are discussed in relation to the in vivo studies of c.s.f. secretion and the mechanisms of active and passive ion transport across other epithelial membranes such as the gall-bladder, intestine and renal proximal tubule.
摘要
利用青蛙脉络丛的体外制备物研究了离子跨脉络膜上皮的转运机制。
钠通过哇巴因敏感的电沉默泵从血管侧主动转运穿过脉络丛至脑室侧表面。与其他上皮膜一样,林格氏液中碳酸氢根离子的存在刺激了钠的转运速率。氯离子和碳酸氢根离子伴随钠在该组织中的净通量。
一些实验表明钾从脑室侧主动转运至浆膜侧表面,且转运速率是细胞外钾浓度的函数。
未获得证据表明钙在该组织中双向主动转运。
乙酰唑胺、乙氧苯唑胺、催产素、加压素、氢化可的松、氨氯吡脒、螺内酯和缺氧均未影响钠的转运。
根据扩散电位测量推断,离子跨脉络丛被动渗透的顺序为P(铷)≈P(钾)>P(铯)≈P(钠)≈P(氯)≈P(碳酸氢根)>P(锂)。至少对于钠、钾和氯,从单向通量测量得出的渗透系数与从电学参数得出的渗透系数之间有良好的相关性。这表明交换扩散作为被动离子转运机制并不重要。
在对称和不对称盐溶液中,瞬时电流-电压曲线均为线性,且发现脉络丛电导与外部盐浓度成正比。这些及其他证据表明,离子跨该上皮被动渗透的主要途径是通过紧密连接途径而非细胞内部。
结合脑脊液分泌的体内研究以及离子在其他上皮膜(如胆囊、肠道和近端肾小管)中主动和被动转运的机制对这些结果进行了讨论。
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