Graber M, DiPaola J, Hsiang F L, Barry C, Pastoriza E
Veterans Affairs Medical Center, Northport 11768.
Am J Physiol. 1991 Dec;261(6 Pt 1):C1143-53. doi: 10.1152/ajpcell.1991.261.6.C1143.
The regulation of intracellular pH (pHi) in the opossum kidney (OK) cell line was studied in vitro using the pH-sensitive excitation ratio of 2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein. Recovery from an NH4Cl acid load disclosed a Na-dependent component blocked by amiloride and a smaller Na-independent component. The Na-independent recovery rate was proportional to the H+ gradient from cell to buffer and was zero in the absence of an electrochemical gradient. The Na-independent recovery was not affected by N-ethylmaleimide, dicyclohexylcarbodiimide, HCO3, phloretin, or ZnCl2 but was accelerated in depolarized cells and by membrane-fluidizing drugs and was inhibited by glutaraldehyde. The apparent cellular buffering capacity changed in proportion to this H+ conductance. Consistent with an electrogenic H+ leak, steady-state cell pH alkalinized with depolarization and acidified with hyperpolarization. Removal of buffer Na+ produced a profound acidification, as did amiloride. In 0-Na+ buffers, extremely large cell-to-buffer H+ gradients were present and proportional to buffer pH. 4-Acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid and 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid had no effect on steady-state pHi. Measurements of intracellular buffering capacity were derived from the change of cell pH induced by withdrawing NH4Cl. This buffering capacity was increased threefold in Na-free buffers, whereas the value measured by direct titration of cell lysate was the same or less than that of control cells. The NH4Cl-derived buffering capacity varied in direct proportion to the magnitude of the H+ leak. Drugs that changed H+ permeability produced the apparent changes of the measured buffering capacity within a few minutes. We conclude that, in HCO3-free buffer, the OK cell uses two membrane acid-base transport pathways: a Na-H antiporter active at physiological pH and a substantial passive H+ conductance. The results also reveal that the NH4Cl-derived buffering capacity is subject to artifacts, possibly due to a finite leak of ionic NH4+.
利用2',7'-双(2-羧乙基)-5(6)-羧基荧光素的pH敏感激发比,在体外研究了负鼠肾(OK)细胞系中细胞内pH(pHi)的调节。从NH4Cl酸负荷中恢复显示出一个被氨氯吡咪阻断的Na依赖成分和一个较小的Na非依赖成分。Na非依赖恢复率与细胞到缓冲液的H+梯度成正比,在没有电化学梯度时为零。Na非依赖恢复不受N-乙基马来酰亚胺、二环己基碳二亚胺、HCO3、根皮素或ZnCl2的影响,但在去极化细胞中以及通过膜流化药物会加速,并且被戊二醛抑制。表观细胞缓冲能力与这种H+电导成比例变化。与电生性H+泄漏一致,稳态细胞pH在去极化时碱化,在超极化时酸化。去除缓冲液中的Na+会导致显著酸化,氨氯吡咪也是如此。在0-Na+缓冲液中,存在极大的细胞到缓冲液的H+梯度,且与缓冲液pH成正比。4-乙酰氨基-4'-异硫氰酸基芪-2,2'-二磺酸和4,4'-二异硫氰酸基芪-2,2'-二磺酸对稳态pHi没有影响。细胞内缓冲能力的测量来自于去除NH4Cl引起的细胞pH变化。这种缓冲能力在无Na缓冲液中增加了三倍,而通过直接滴定细胞裂解物测得的值与对照细胞相同或更低。源自NH4Cl的缓冲能力与H+泄漏的大小直接成比例变化。改变H+通透性的药物在几分钟内就会使测得的缓冲能力产生明显变化。我们得出结论,在无HCO3缓冲液中,OK细胞使用两种膜酸碱转运途径:一种在生理pH下活跃的Na-H反向转运体和一种大量的被动H+电导。结果还表明,源自NH4Cl的缓冲能力可能存在假象,可能是由于离子NH4+的有限泄漏。
