大鼠肾近球小管细胞胞饮体膜氢泵活性和水的渗透性转运的特征

本实验采用异硫氰酸-葡聚糖荧光素(fluorescein isothiocyanate-dextran,FITC-dextran)体内标记法,研究大鼠肾近球小管细胞胞饮体(endosome)膜上 H~+-ATP 酶的活性及水的渗透性转运。通过观察在胞饮体外加入一定量 ATP 后,胞饮体内 pH 值的时间反应曲线,从而测定 ATP-依赖的 H~+在胞饮体膜上的转运情况。胞饮体内的酸化速度及 pH 的最低值与加入的 ATP 浓度有关。在加入 ATP 前,胞饮体内的 pH 值为7.4,加入不同浓度的 ATP 后,即[ATP]为0.005,0.05,0.5,5和10mmol/L,胞饮体内 pH 最低值分别为7.30,6.99,6.68,6.38和6.39。此种由 ATP 引起的酸化反应,被0.5mmol/L N-ethylmaleimide(NEM)抑制97%,但不被钒酸盐和 oligomycin 所抑制。实验还同时观察了此种胞饮体水的渗透性转运机制。通过在胞饮体膜内外建立一个蔗糖浓度梯度。观察 FITC-dextran 荧光信号的快速动力学变化过程,从而测定由于渗透压梯度引起的水在胞饮体膜上转运的特征。在230℃时,水的渗透性通透系数(osmotic water permeability coefficient,P_f)为0.03cm/s;加入0.5mmol/L HgCl_2后,水的转运被抑制70%。此抑制反应可被5mmol/L 巯基乙醇(β-Mcrcaptoethanol)完全逆转。上述结果提示:大鼠肾近球小管胞饮体膜含有H~+-ATP 酶和水的转运通道。胞饮     

The action of organic mercurials on the erythrocyte membrane

The solubilisation of proteins from erythrocyte membranes by treatment with organic mercurials has been studied with different species. The marked solubilisation previously reported for human membranes does not seem to be a general phenomenon. All of the other species examined showed less than 50% of the solubilisation shown by human membranes. The protein-solubilising effect seems to be dependent on hydrophobic mercury derivatives carrying a net negative charge. Uncharged compounds like phenylmercuric acetate blocked the effect, although $\text{N-}\text{ethylmaleimide}$ and iodoacetamide did not. With the aid of radioactively labelled compounds, and of atomic absorption spectrophotometry, the proteins reactive towards the mercurials were identified. The major integral protein, band 3, was the major protein capable of binding the mercurial. Reaction with the mercurial appears to disrupt interaction of band 3 with bands 2.1 and 4.2, allowing dissociation of the cytoskeleton from the membrane. In addition, band 4.9 was also found to react with the mercurials, possibly resulting in disruption of the cytoskeleton.     

Studies on the fragmentation of erythrocyte ghost membrane with p-chloromercuribenzoate in the micromolar range

The effects of nonsaturating amounts (5–60 nmol/mg membrane protein) of $\text{p-}\text{chloromercuribenzoate}$ on the stability of unsealed erythrocyte ghosts were studied by turbidimetric measurements and direct observation by phase contrast microscopy. The organic mercurial provokes drastic disorganization of the membrane involving vesicle formation by inter- and externalization of the bilayer. These effects are not associated with a release in solution of membrane proteins which was shown in previous studies to occur at higher $\text{p-}\text{chloromercuribenzoate}$ concentration. Attempts have been made to identify the proteins involved in this phenomenon by the use of nonsaturating amounts of radioactively-labelled $\text{p-}\text{chloromercuribenzoate}$. Actin and band 3 protein which are the first to be labelled, represent plausible candidates as sensitive targets for the disrupting organic mercurial. Stroma obtained from spherocytes did not show significant differences with normocytes in their stability with regard to $\text{p-}\text{chloromercuribenzoate}$. Other reagents including $\text{N-}\text{ethylmaleimide}$, diamide and DNAase I were also studied. The results suggest strongly that the integrity of the sulfhydryl groups of actin, as well as those of band 3 protein, is essential for the stability of the erythrocyte membrane.     

Comparative effect of metals on antidiuretic hormone induced transport in toad bladder: specificity of mercuric inhibition of water channels

We previously reported that HgCl₂ inhibits water and urea flux in tissues fixed with glutaraldehyde after antidiuretic hormone (ADH) stimulation and suggested that the ADH-induced water channel may share characteristics of the red blood cell and proximal tubule water transport pathway. To determine the specificity of mercury's action, we examined the effect of numerous other metals. In tissues fixed after ADH stimulation, water flow and urea and sucrose permeabilities are maintained from mucosal bath pH 2.5 through pH 12. Several metals including Ba, Co, Fe, Sr and Zn did not alter flux. Al, Cd, La, Li, Pb and U inhibited urea permeability but not water flow. At pH 2.8, Cu inhibited water flow by 30% and urea permeability by 50%. At pH 4.9–7.4, Cu inhibited urea permeability but not water flow. At pH 3.0, Pt inhibited flow in ADH-pretreated tissues. The inhibitory effect was not present at pH>3.0. At pH<3.0, Au inhibited flow by 90% in tissues fixed after pretreatment with ADH but increased the permeability of tissues fixed in the absence of ADH. Ag inhibited flow by 70% but also increased sucrose, urea, and basal permeabilities. This suggests that Ag and Au disrupt epithelial integrity. These results indicate that at physiologic pH, the ADH-induced water channel is specifically blocked by Hg but not by other metals. This specificity may reflect the presence of a large number of sulfhydryl groups in the water channel.