Hoffmann E K
Biochim Biophys Acta. 1986 Jun 12;864(1):1-31. doi: 10.1016/0304-4157(86)90014-6.
In the case of the red blood cell, anion transport is a highly specific one-for-one exchange catalyzed by a major membrane protein known as band 3 or as capnophorin. This red cell anion-exchange system mediates the Cl-(-)HCO3- exchange responsible for most of the bicarbonate transport capacity of the blood. The rapidly expanding knowledge of the molecular biology and the transport kinetics of this specialized transport system is very briefly reviewed in Section III. Exchange diffusion mechanisms for anions are found in many cells other than erythrocytes. The exchange diffusion system in Ehrlich cells has several similarities to that in red cells. In several cell types (subsection IV-B), there is evidence that intracellular pH regulation depends on Cl-(-)HCO3- exchange processes. Anion exchange in other single cells is described in Section IV, and its role in pH regulation is described in Section VII. Anion exchange mechanism operating in parallel with, and only functionally linked to Na+-H+ or K+-H+ exchange mechanisms can also play a role in cell volume regulation as described in Section VII. In the Ehrlich ascites cell and other vertebrate cells, electroneutral anion transfer has been found to occur also by a cotransport system for cations and chloride operating in parallel with the exchange diffusion system. The cotransport system is capable of mediating secondary active chloride influx. In avian red cells, the cotransport system has been shown to be activated by adrenergic agonists and by cyclic AMP, suggesting that the cotransport is involved in regulatory processes (see subsection V-A.). In several cell types, cotransport systems are activated and play a role during volume regulation, as described in Section V and in Section VII. It is also likely that this secondary active cotransport of chloride plays a significant role for the apparently active extrusion of acid equivalents from certain cells. If a continuous influx of chloride against an electrochemical gradient is maintained by a cotransport system, the chloride disequilibrium can drive an influx of bicarbonate through the anion exchange mechanism, as described in Section VII. Finally, even the electrodiffusion of anions is shown to be regulated, and in Ehrlich cells and human lymphocytes an activation of the anion diffusion pathway plays a major role in cell volume regulation as described in Section VI and subsection VII-B.(ABSTRACT TRUNCATED AT 250 WORDS)
就红细胞而言,阴离子转运是一种高度特异性的一对一交换,由一种主要的膜蛋白催化,这种膜蛋白称为带3蛋白或碳酸酐酶。这种红细胞阴离子交换系统介导Cl-(-)HCO3-交换,这一交换负责血液中大部分的碳酸氢盐运输能力。第三节简要回顾了关于这个特殊转运系统的分子生物学和转运动力学的快速增长的知识。除红细胞外,许多细胞中都存在阴离子交换扩散机制。艾氏腹水癌细胞中的交换扩散系统与红细胞中的有一些相似之处。在几种细胞类型中(第四节B部分),有证据表明细胞内pH调节取决于Cl-(-)HCO3-交换过程。第四节描述了其他单细胞中的阴离子交换,第七节描述了其在pH调节中的作用。与Na+-H+或K+-H+交换机制并行运行且仅在功能上相关联的阴离子交换机制,如第七节所述,在细胞体积调节中也可发挥作用。在艾氏腹水癌细胞和其他脊椎动物细胞中,已发现电中性阴离子转运也可通过与交换扩散系统并行运行的阳离子和氯离子共转运系统发生。该共转运系统能够介导继发性主动氯离子内流。在鸟类红细胞中,已证明共转运系统可被肾上腺素能激动剂和环磷酸腺苷激活,这表明共转运参与调节过程(见第五节A部分)。如第五节和第七节所述,在几种细胞类型中,共转运系统在体积调节过程中被激活并发挥作用。氯化物的这种继发性主动共转运很可能在某些细胞明显主动排出酸当量的过程中起重要作用。如果共转运系统维持氯离子逆电化学梯度的持续内流,氯离子的不平衡可驱动碳酸氢根通过阴离子交换机制内流,如第七节所述。最后,甚至阴离子的电扩散也显示受到调节,在艾氏腹水癌细胞和人淋巴细胞中,阴离子扩散途径的激活在细胞体积调节中起主要作用,如第六节和第七节B部分所述。(摘要截取自250词)
