红细胞和胸腺细胞对3,5,3'-三碘甲状腺原氨酸及甲状腺素的细胞摄取。

Galton V A, St Germain D L, Whittemore S

Endocrinology. 1986 May;118(5):1918-23. doi: 10.1210/endo-118-5-1918.

During recent studies of receptor binding of T3 and T4 in tadpole red blood cells (RBCs), it was found that the fractional uptake of T3 was 3-5 times greater than that of T4. The present studies were performed to determine if this difference was due to facilitated uptake of T3. All studies were performed in cells incubated at 22 C in phosphate-buffered amphibian or mammalian Ringer solution containing 10(-11) M [125I]T3 or [125I]T4, with or without nonradioactive L-T3, D-T3, or L-T4 in concentrations ranging from 10(-10) to 2 X 10(-7) M. In tadpole, frog, rat, and human RBCs and in rat thymus cells, the rate of uptake of [125I]T3 and its appearance in the cytosol (extranuclear) fraction of the cell was greatly retarded in the presence of 10(-7) M T3. This effect was not due to saturation of the T3-binding proteins in cytosol, since the presence of 10(-7) M T3 did not influence the percentage of [125I]T3 in cytosol at equilibrium. These data suggest the presence of a saturable system for the cellular uptake of T3. T4 (10(-7) M) had relatively little effect, and D-T3 (10(-7) M) had no effect on this system. No saturable system for T4 uptake could be demonstrated, and at low concentrations of hormone, T4 uptake was only 10-30% of T3 uptake, although the binding activities of cytosol and cellular uptake via nonsaturable systems were quantitatively similar for both hormones. From kinetic studies of [125I]T3 uptake, it was found that at low concentrations of T3 (10(-11)-10(-9) M), the saturable system accounted for more than 60% of the total uptake of [125I]T3. The apparent Km values of the saturable system in RBCs of tadpole, frog, and rat were 4.5 +/- 0.09 (+/- SE), 5.7 +/- 1.10, and 4.6 +/- 0.73 X 10(-8) M T3, respectively. Corresponding values for maximum velocity were 5.92 +/- 1.02, 2.86 +/- 0.70, and 2.08 +/- 0.34 pmol/min X 10(7) cells. In rat thymus cells, the Km was 16.9 +/- 0.93 X 10(-8) M, and the maximum velocity was 9.10 +/- 0.5 pmol/min X 10(7) cells. The saturable uptake system was not influenced by ouabain, dinitrophenol, sodium fluoride, oligomycin, or sodium cyanide. These findings suggest that the uptake of T3, but not T4, into some tissues is facilitated by a specific carrier-mediated system that is not dependent on metabolic energy.(ABSTRACT TRUNCATED AT 400 WORDS)

在最近对蝌蚪红细胞（RBCs）中T3和T4受体结合的研究中，发现T3的摄取分数比T4大3至5倍。进行本研究以确定这种差异是否归因于T3的易化摄取。所有研究均在22℃下于含有10^(-11)M [125I]T3或[125I]T4的磷酸盐缓冲两栖类或哺乳类任氏液中孵育的细胞中进行，添加或不添加浓度范围为10^(-10)至2×10^(-7)M的非放射性L-T3、D-T3或L-T4。在蝌蚪、青蛙、大鼠和人类的红细胞以及大鼠胸腺细胞中，在存在10^(-7)M T3的情况下，[125I]T3的摄取速率及其在细胞胞质溶胶（核外）部分的出现被极大地延迟。这种效应并非由于胞质溶胶中T3结合蛋白的饱和，因为存在10^(-7)M T3并不影响平衡时胞质溶胶中[125I]T3的百分比。这些数据表明存在一种可饱和的T3细胞摄取系统。T4（10^(-7)M）对此系统影响相对较小，而D-T3（10^(-7)M）对此系统无影响。未证明存在T4摄取的可饱和系统，并且在低浓度激素时，T4摄取仅为T3摄取的10%至30%，尽管两种激素通过非饱和系统的胞质溶胶结合活性和细胞摄取在数量上相似。从[125I]T3摄取的动力学研究发现，在低浓度T3（10^(-11) - 10^(-9)M）时，可饱和系统占[125I]T3总摄取量的60%以上。蝌蚪、青蛙和大鼠红细胞中可饱和系统的表观Km值分别为4.5±0.09（±SE）、5.7±1.10和4.6±0.73×10^(-8)M T3。最大速度的相应值分别为5.92±1.02、2.86±0.70和2.08±0.34 pmol/min×10^7个细胞。在大鼠胸腺细胞中，Km为16.9±0.93×10^(-8)M，最大速度为9.10±0.5 pmol/min×10^7个细胞。可饱和摄取系统不受哇巴因、二硝基苯酚、氟化钠、寡霉素或氰化钠的影响。这些发现表明，T（下标3）而非T4进入某些组织是由一种不依赖代谢能量的特定载体介导系统所促进的。（摘要截断于400字）