人类红细胞中的甘氨酸转运
Glycine transport in human erythrocytes.
作者信息
Ellory J C, Jones S E, Young J D
出版信息
J Physiol. 1981 Nov;320:403-22. doi: 10.1113/jphysiol.1981.sp013958.
Abstract
- Glycine transport in human erythrocytes was resolved into five separate components of uptake. The first and major component of uptake was transport by a high-affinity (apparent Km 25 microM) Na+- and Cl- -dependent system. This system was specific for glycine, sarcosine and proline; Br- but not I- was able to substitute for Cl-. Uptake by this route was inhibited less than 20% by the loop diuretics, bumetanide and furosemide (10(-4) M), suggesting that it was distinct from the Cl- -dependent system responsible for Na+/K+ transport. Its properties closely resembled those of the gly transport system described previously in avian erythrocytes. 2. The second uptake route was transport by the Na+-dependent, Cl- -independent small neutral amino acid transport system (designated ASC). Neither NA+-dependent uptake route was present in sheep erythrocytes. 3. Two Na+-independent uptake mechanisms were also identified; first, uptake by the amino acid transport system (designated L), and secondly, SITS-sensitive uptake by the anion-exchange (band 3) transport mechanism (SITS is 4-acetamido-4'-iso-thiocyanatostilbene-2,2'-disulphonic acid, an effective inhibitor of anion transport by this route). Uptake by the latter route was increased markedly when fluxes were measured in isotonic SO42- medium or when the pH was increased. 4. At 0.2 mM extracellular glycine, the relative contributions of each of these uptake routes to the total glycine flux were 42, 11, 15 and 16% for the gly, ASC, L and band 3 systems, respectively. 5. Finally, there was a residual Na+-independent component of glycine uptake which contributed 16% of the total flux. With the exception of the gly system, all uptake routes showed a linear concentration dependence up to 2 mM-glycine.
摘要
- 人红细胞中的甘氨酸转运可分为五个独立的摄取成分。摄取的第一个也是主要成分是通过高亲和力(表观 Km 为 25 μM)的 Na⁺ 和 Cl⁻ 依赖性系统进行转运。该系统对甘氨酸、肌氨酸和脯氨酸具有特异性;Br⁻ 而非 I⁻ 能够替代 Cl⁻。通过该途径的摄取受髓袢利尿剂布美他尼和呋塞米(10⁻⁴ M)抑制不到 20%,这表明它与负责 Na⁺/K⁺ 转运的 Cl⁻ 依赖性系统不同。其特性与先前在禽红细胞中描述的甘氨酸转运系统非常相似。2. 第二条摄取途径是通过 Na⁺ 依赖性、Cl⁻ 非依赖性的小中性氨基酸转运系统(称为 ASC)进行转运。绵羊红细胞中不存在任何一种 Na⁺ 依赖性摄取途径。3. 还鉴定出两种 Na⁺ 非依赖性摄取机制;第一种是通过氨基酸转运系统(称为 L)进行摄取,第二种是通过阴离子交换(带 3)转运机制进行 SITS 敏感摄取(SITS 是 4-乙酰氨基-4'-异硫氰酸根合芪-2,2'-二磺酸,该途径阴离子转运的有效抑制剂)。当在等渗 SO₄²⁻ 介质中测量通量或当 pH 升高时,通过后一种途径的摄取显著增加。4. 在细胞外甘氨酸浓度为 0.2 mM 时,这些摄取途径中每一种对总甘氨酸通量的相对贡献分别为:甘氨酸系统 42%、ASC 系统 11%、L 系统 15% 和带 3 系统 16%。5. 最后,存在一个残余的 Na⁺ 非依赖性甘氨酸摄取成分,占总通量的 16%。除甘氨酸系统外,所有摄取途径在甘氨酸浓度高达 2 mM 时均表现出线性浓度依赖性。
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