Zapf A, Hsu D, Olefsky J M
Department of Medicine, University of California-San Diego School of Medicine, La Jolla 92093.
Endocrinology. 1994 Jun;134(6):2445-52. doi: 10.1210/endo.134.6.8194471.
In this study we have compared the intracellular itineraries of insulin and insulin-like growth factor-I (IGF-I) and their receptors subsequent to ligand internalization in rat fibroblasts. We found that the endocytic rate constant is approximately 3 times as high for insulin as for IGF-I. The dissociation of internalized ligand from its receptor was monitored by the ability of ligand-receptor complexes to precipitate in the presence of polyethylene glycol (PEG). Insulin loses its ability to precipitate with PEG more rapidly than IGF-I. After 60 min, less than 10% of the intracellular insulin remains PEG precipitable, whereas 44% of intracellular IGF-I stays PEG precipitable. Ligand degradation was determined by precipitation with trichloroacetic acid (TCA). Insulin degradation after internalization is more rapid compared with IGF-I degradation; after 2 h, 80% of intracellular IGF-I, in contrast to only 30% of intracellular insulin, remains intact. We measured retroendocytosis of insulin and IGF-I by assessing the amount of internalized ligand that was subsequently released from the cells. When analyzing released ligand by TCA precipitation, we found that 25% of insulin and 53% of IGF-I were TCA precipitable. After 120 min, only 16% of insulin and 43% of IGF-I remained intracellular. To provide insight into a possible mechanism that prevents IGF-I from being subjected to the same degree of degradation as insulin, we studied the effect of pH on IGF-I and insulin binding. We found IGF-I binding to be less sensitive to decreases in pH compared with insulin binding. Therefore, it is likely that after internalization, IGF-I does not dissociate from its intracellular receptor as easily as insulin in the acidifying endosome and, therefore, can return to the cell surface via a recycling receptor. In summary, we have observed distinct differences in the intracellular itineraries of IGF-I and insulin and their receptors. IGF-I internalization and degradation proceed less efficiently than insulin internalization, and IGF-I is preferentially targeted into a retroendocytotic pathway in contrast to insulin, which primarily undergoes lysosomal degradation. The differential effect of pH on ligand binding to these structurally related hormone receptors may account for the quantitatively distinct ligand trafficking events.
在本研究中,我们比较了胰岛素和胰岛素样生长因子-I(IGF-I)及其受体在大鼠成纤维细胞中配体内化后的细胞内行程。我们发现,胰岛素的内吞速率常数约为IGF-I的3倍。通过配体-受体复合物在聚乙二醇(PEG)存在下沉淀的能力来监测内化配体与其受体的解离。胰岛素比IGF-I更快地失去与PEG沉淀的能力。60分钟后,细胞内胰岛素中仍可被PEG沉淀的不到10%,而细胞内IGF-I中有44%仍可被PEG沉淀。通过用三氯乙酸(TCA)沉淀来测定配体降解。内化后胰岛素的降解比IGF-I的降解更快;2小时后,细胞内80%的IGF-I保持完整,相比之下,细胞内胰岛素只有30%保持完整。我们通过评估随后从细胞中释放的内化配体的量来测量胰岛素和IGF-I的逆向内吞作用。当通过TCA沉淀分析释放的配体时,我们发现25%的胰岛素和53%的IGF-I可被TCA沉淀。120分钟后,只有16%的胰岛素和43%的IGF-I仍留在细胞内。为了深入了解一种可能防止IGF-I遭受与胰岛素相同程度降解的机制,我们研究了pH对IGF-I和胰岛素结合的影响。我们发现,与胰岛素结合相比,IGF-I结合对pH降低的敏感性较低。因此,内化后,IGF-I在酸化的内体中可能不像胰岛素那样容易与其细胞内受体解离,因此可以通过回收受体返回细胞表面。总之,我们观察到IGF-I和胰岛素及其受体在细胞内行程上存在明显差异。IGF-I的内化和降解效率低于胰岛素内化,与主要经历溶酶体降解的胰岛素相反,IGF-I优先进入逆向内吞途径。pH对这些结构相关激素受体配体结合的差异作用可能解释了定量上不同的配体转运事件。
