Wahl M L, Pooler P M, Briand P, Leeper D B, Owen C S
Department of Biochemistry and Molecular Pharmacology, Thomas Jefferson University, Philadelphia, Pennsylvania 19107, USA.
J Cell Physiol. 2000 Jun;183(3):373-80. doi: 10.1002/(SICI)1097-4652(200006)183:3<373::AID-JCP10>3.0.CO;2-S.
Tumor cells in vivo often exist in an ischemic microenvironment that would compromise the growth of normal cells. To minimize intracellular acidification under these conditions, these cells are thought to upregulate H(+) transport mechanisms and/or slow the rate at which metabolic processes generate intracellular protons. Proton extrusion has been compared under identical conditions in two closely related human breast cell lines: nonmalignant but immortalized HMT-3522/S1 and malignant HMT-3522/T4-2 cells derived from them. Only the latter were capable of tumor formation in host animals or long-term growth in a low-pH medium designed to mimic conditions in many solid tumors. However, detailed study of the dynamics of proton extrusion in the two cell lines revealed no significant differences. Thus, even though the ability to upregulate proton extrusion in a low pH environment (pH(e)) may be important for cell survival in a tumor, this ability is not acquired along with the capacity to form solid tumors and is not unique to the transformed cell. This conclusion was based on fluorescence measurements of intracellular pH (pH(i)) on cells that were plated on extracellular matrix, allowing them to remain adherent to proteins to which they had become attached 24 to 48 h earlier. Proton translocation under conditions of low pH(e) was observed by monitoring pH(i) after exposing cells to an acute acidification of the surrounding medium. Proton translocation at normal pH(e) was measured by monitoring the recovery after introduction of an intracellular proton load by treatment with ammonium chloride. Even in the presence of inhibitors of the three major mechanisms of proton translocation (sodium-proton antiport, bicarbonate transport, and proton-lactate symport) together with acidification of their medium, cells showed only about 0.4 units of reduction in pH(i). This was attributed to a slowing of metabolic proton generation because the inhibitors were shown to be effective when the same cells were given an intracellular acidification.
体内肿瘤细胞常常存在于缺血微环境中,这种环境会抑制正常细胞的生长。为了在这些条件下使细胞内酸化程度降至最低,人们认为这些细胞会上调氢离子转运机制和/或减缓代谢过程产生细胞内质子的速率。在相同条件下,对两种密切相关的人乳腺细胞系进行了质子外排比较:非恶性但永生化的HMT - 3522/S1细胞系以及由其衍生的恶性HMT - 3522/T4 - 2细胞系。只有后者能够在宿主动物体内形成肿瘤,或者在模拟许多实体瘤环境的低pH培养基中长期生长。然而,对这两种细胞系中质子外排动力学的详细研究表明,二者并无显著差异。因此,尽管在低pH环境(pH(e))中上调质子外排的能力对于肿瘤细胞的存活可能很重要,但这种能力并非随着形成实体瘤的能力一同获得,也并非转化细胞所特有。这一结论基于对铺在细胞外基质上的细胞进行细胞内pH(pH(i))的荧光测量,这些细胞能够在24至48小时前附着的蛋白质上保持贴壁状态。通过监测细胞暴露于周围培养基急性酸化后的pH(i)来观察低pH(e)条件下的质子转运。通过监测用氯化铵处理引入细胞内质子负荷后的恢复情况来测量正常pH(e)条件下的质子转运。即使在存在质子转运的三种主要机制(钠 - 质子反向转运、碳酸氢盐转运和质子 - 乳酸同向转运)抑制剂的情况下,同时对其培养基进行酸化处理,细胞的pH(i)仅降低约0.4个单位。这归因于代谢性质子产生的减缓,因为当对相同细胞进行细胞内酸化时,这些抑制剂显示出有效作用。
