Johanson C E, Murphy V A
Department of Clinical Neurosciences, Brown University/Rhode Island Hospital, Providence 02902.
Am J Physiol. 1990 Jun;258(6 Pt 2):F1538-46. doi: 10.1152/ajprenal.1990.258.6.F1538.
Agents that inhibit or stimulate Na+ transport were tested for their effects on the ionic composition and volume of the in vivo choroid plexus (CP) epithelium. Ketamine-anesthetized adult Sprague-Dawley rats treated 1 h with acetazolamide or insulin were analyzed for choroid cell [Na+]i, [HCO3-]i, and pHi (dimethadione method); for transmembrane Na+ and H+ gradients; and for the kinetics of penetration of 22Na from plasma to plexus epithelium to CSF. Acetazolamide (25 mg/kg) reduced [Na+]i by 5-10 mmol/l and substantially elevated [HCO3-]i and pHi; the concurrent 22Na uptake by the in vivo choroid plexus and CSF, as quantified by the transfer coefficient, Kin (ml.g-1.h-1), was curtailed by 55-60%. Such effects on Na+ transport and distribution are likely secondary to the alkalinization of pHi induced by carbonic anhydrase inhibition. Conversely, insulin (3 U/kg ip) stimulated Na+ transport, i.e., manifested as enhanced uptake of 22Na from plasma to choroid cell and increased [Na+]i. For various treatments altering the basolateral membrane H+ gradient, the regression analysis of the 22Na Kin vs. log [H+]i/[H+]ISF (where ISF is interstitial fluid) was significant at P less than 0.01. This is consistent with effects mediated by Na(+)-H+ exchange. K+ and Cl- redistribution phenomena were coincident with altered Na+ transport, as choroidal cells retained K+, Cl-, and H2O after acetazolamide but lost K+, Cl-, and H2O with insulin treatment. A model is presented relating alterations in CP Na+ transport, KCl content, and cell volume. Overall, the findings encourage the postulate for effects of these drugs on Na+ transport basolaterally, either indirectly by attenuating [H+]i/[H+]ISF (acetazolamide) or directly by accelerating Na+ transport (insulin).
对抑制或刺激钠转运的药物进行了测试,以观察它们对体内脉络丛(CP)上皮细胞离子组成和体积的影响。对用乙酰唑胺或胰岛素处理1小时的氯胺酮麻醉成年Sprague-Dawley大鼠,分析脉络丛细胞的细胞内钠离子浓度([Na⁺]i)、细胞内碳酸氢根离子浓度([HCO₃⁻]i)和细胞内pH值(二甲基酮肟法);分析跨膜钠和氢梯度;以及分析²²Na从血浆穿透到脉络丛上皮再到脑脊液的动力学。乙酰唑胺(25毫克/千克)使[Na⁺]i降低5 - 10毫摩尔/升,并显著升高[HCO₃⁻]i和细胞内pH值;通过转运系数Kin(毫升·克⁻¹·小时⁻¹)定量的体内脉络丛和脑脊液对²²Na的同时摄取减少了55 - 60%。对钠转运和分布的这种影响可能继发于碳酸酐酶抑制引起的细胞内pH值碱化。相反,胰岛素(3单位/千克腹腔注射)刺激钠转运,即表现为从血浆到脉络丛细胞对²²Na的摄取增加以及[Na⁺]i升高。对于改变基底外侧膜氢梯度的各种处理,²²Na的Kin与log [H⁺]i/[H⁺]ISF(其中ISF是细胞间液)的回归分析在P小于0.01时具有显著性。这与钠氢交换介导的作用一致。钾和氯的重新分布现象与钠转运的改变同时发生,因为脉络丛细胞在乙酰唑胺处理后保留了钾、氯和水,但在胰岛素处理后失去了钾、氯和水。提出了一个关于脉络丛钠转运、氯化钾含量和细胞体积改变之间关系的模型。总体而言,这些发现支持这样一种假设,即这些药物通过减弱[H⁺]i/[H⁺]ISF间接(乙酰唑胺)或直接通过加速钠转运(胰岛素)对基底外侧的钠转运产生影响。
