Bascom C C, Sharifi B G, Melkerson L J, Rintoul D A, Johnson T C
J Cell Physiol. 1985 Dec;125(3):427-35. doi: 10.1002/jcp.1041250310.
We have isolated and characterized glycopeptides, derived from mouse and bovine cerebral cortex cells, that inhibit protein synthesis and cell growth of normal but not transformed cells. The inhibitor binds to target cell surfaces, and gangliosides have previously been shown to influence cell sensitivity to the glycopeptides. Preincubation with 3.0 micrograms/ml ganglioside GM1 at 0 degrees C for 3 hr sensitized the mouse L-cell line to the inhibitor, as determined by protein synthesis assays. Preincubation of LM cells with ganglioside GM1 alone did not affect protein synthesis rates. In addition, the gangliosides GD1a and GM3 also sensitized the LM cells to the protein synthesis inhibitory effect of the glycopeptide inhibitor. Binding experiments were performed with 3T3 (sensitive) and LM (insensitive) cells to determine if sensitivity to the glycopeptide inhibitor was reflected in binding of the inhibitor to these cells. Binding of 125I-labeled inhibitor to 3T3 cells was maximal after 60 min at 0 degrees C and saturable at approximately 1 X 10(4) molecules/cell. Furthermore, binding of the inhibitor was dose-dependent, with half-maximal binding at 1.5-2.0 nM and saturation at 8.0-10.0 nM. Scatchard plot analysis indicated that the Kd was about 1 X 10(-9) M and that there are 1 X 10(4) receptors/cell. Binding of the inhibitor to LM cells was maximal after 30 min at 0 degrees C and saturation occurred at 5 X 10(3) molecules/cell. We then examined the possibility that gangliosides are the cellular receptor or co-receptor for the glycopeptide inhibitor. Binding of the inhibitor to ganglioside GM1 was first examined after the ganglioside had been preadsorbed to polystyrene tubes. These experiments indicated that the ganglioside did not bind the inhibitor. Ganglioside-containing liposomes from phosphatidylcholine or LM cell membrane components were also prepared; these artificial membranes did not bind appreciable amounts of the iodinated inhibitor. Competition experiments showed that the gangliosides GM1 and GD1a did not neutralize the protein synthesis inhibitory activity of the glycopeptides, indicating that gangliosides do not directly interact with the glycopeptide inhibitor. In addition, binding of the inhibitor to LM cells preincubated with ganglioside GM1 was studied. Although the binding of the inhibitor to LM cells was one-half that observed for 3T3 cells, incorporation of exogenous gangliosides into LM cells did not result in increased binding of the inhibitor.(ABSTRACT TRUNCATED AT 400 WORDS)
我们已经分离并鉴定了源自小鼠和牛大脑皮层细胞的糖肽,这些糖肽可抑制正常细胞而非转化细胞的蛋白质合成和细胞生长。该抑制剂与靶细胞表面结合,并且先前已表明神经节苷脂会影响细胞对糖肽的敏感性。通过蛋白质合成测定法确定,在0℃下用3.0微克/毫升神经节苷脂GM1预孵育3小时可使小鼠L细胞系对该抑制剂敏感。单独用神经节苷脂GM1预孵育LM细胞不会影响蛋白质合成速率。此外,神经节苷脂GD1a和GM3也使LM细胞对糖肽抑制剂的蛋白质合成抑制作用敏感。用3T3(敏感)细胞和LM(不敏感)细胞进行结合实验,以确定对糖肽抑制剂的敏感性是否反映在该抑制剂与这些细胞的结合上。在0℃下60分钟后,125I标记的抑制剂与3T3细胞的结合达到最大值,并且在约1×10(4)个分子/细胞时达到饱和。此外,抑制剂的结合是剂量依赖性的,半数最大结合在1.5 - 2.0 nM,8.0 - 10.0 nM时达到饱和。Scatchard图分析表明,解离常数(Kd)约为1×10(-9) M,每个细胞有1×10(4)个受体。在0℃下30分钟后,抑制剂与LM细胞的结合达到最大值,在5×10(3)个分子/细胞时达到饱和。然后我们研究了神经节苷脂是否是糖肽抑制剂的细胞受体或共受体的可能性。在神经节苷脂预吸附到聚苯乙烯管后,首先检测了抑制剂与神经节苷脂GM1的结合。这些实验表明该神经节苷脂不结合抑制剂。还制备了来自磷脂酰胆碱或LM细胞膜成分的含神经节苷脂脂质体;这些人工膜没有结合可观量的碘化抑制剂。竞争实验表明,神经节苷脂GM1和GD1a不会中和糖肽的蛋白质合成抑制活性,这表明神经节苷脂不会直接与糖肽抑制剂相互作用。此外,研究了抑制剂与用神经节苷脂GM1预孵育的LM细胞的结合。尽管抑制剂与LM细胞的结合是3T3细胞观察值的一半,但将外源性神经节苷脂掺入LM细胞并未导致抑制剂结合增加。(摘要截短于400字)
