糖转运调节:NADH CoQ还原酶缺乏在两种细胞培养系统中影响的比较表征。

R J Germinario, L Continelli, S Pratt
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引用次数: 1

摘要

在本报告中,我们描述了在两种不同的呼吸缺陷成纤维细胞培养中葡萄糖转运的上调。我们已经证明,通过2脱氧d -葡萄糖转运测量,葡萄糖转运在呼吸缺陷细胞中增加,并且与MCH55正常人和V79亲代中国仓鼠细胞系相比,在WG750人和G14中国仓鼠成纤维细胞呼吸缺陷细胞系中都很容易观察到。利用亚细胞分离技术,GLUT 1葡萄糖转运蛋白主要位于人和仓鼠细胞系的质膜富集部分。在人类细胞中,在WG750呼吸缺陷突变细胞的质膜富集部分中,GLUT 1葡萄糖转运蛋白的表达升高了三倍。在中国仓鼠细胞系中,呼吸缺陷的G14细胞在质膜富集部分没有表现出GLUT - 1葡萄糖转运蛋白的升高,但葡萄糖转运蛋白的表达增加了2倍以上。此外,与V79亲本细胞系相比,G14细胞的质膜组分中GLUT - 1葡萄糖转运蛋白含量相似。通过Western blot分析,G14细胞中的GLUT 1葡萄糖转运蛋白在聚丙烯酰胺凝胶上的迁移率与V79细胞系中的GLUT 1葡萄糖转运蛋白的迁移率不同。仓鼠细胞中葡萄糖转运体的这种不同移动性似乎与葡萄糖转运体的糖基化差异有关。正常人和仓鼠细胞在胰岛素刺激下糖转运显著增加(P < 0.05),而呼吸缺陷细胞在胰岛素刺激下糖转运无显著增加(P > 0.05)。此外,与正常细胞相比,人WG750突变细胞中GLUT 1 mRNA的表达升高。胰岛素暴露显著增加人细胞GLUT - 1 mRNA表达(P < 0.05)。在两种仓鼠细胞系中没有观察到GLUT - 1 mRNA的差异。因此,两种呼吸缺陷细胞系都具有胰岛素抵抗性(即,就胰岛素刺激的糖转运而言)。呼吸缺陷突变导致人类和仓鼠细胞中糖转运增加;然而,人类细胞通过增加其GLUT - 1 mRNA水平和最终膜定位葡萄糖转运蛋白水平来适应突变。另一方面,仓鼠细胞通过糖基化明显地改变其葡萄糖转运蛋白的内在活性来适应。我们认为这些细胞系统可以作为研究脊椎动物细胞中糖转运调节的多种因素的有效模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Sugar transport regulation: comparative characterization of the effect of NADH CoQ reductase deficiency in two cell culture systems.

In this report, we have characterized the upregulation of glucose transport in two different respiration-deficient fibroblast cell cultures. We have demonstrated that glucose transport increases in respiration-deficient cells as measured by 2 deoxy D-glucose transport and is readily observed in both the WG750 human and G14 Chinese hamster fibroblast respiration-deficient cell lines when compared with the MCH55 normal human and V79 parental Chinese hamster cell lines, respectively. Using subcellular fractionation techniques, the GLUT 1 glucose transporter was found located predominantly in the plasma membrane-enriched fraction of the human and hamster cell lines. In human cells, the expression of the GLUT 1 glucose transporter was elevated three-fold in the plasma membrane-enriched fraction of the WG750 respiration-deficient mutant cells. In the Chinese hamster cell lines, the respiration-deficient G14 cells exhibited no such GLUT 1 glucose transporter elevation in the plasma membrane-enriched fraction, yet expressed a >2-fold increase in glucose transport. Furthermore, the G14 cells had a similar content of GLUT 1 glucose transporter in the plasma membrane fraction when compared with the V79 parental cell line. Using Western blot analysis, the GLUT 1 glucose transporter in G14 cells exhibited a different mobility on a polyacrylamide gel when compared with the mobility of the GLUT 1 glucose transporter of the V79 cell line. This differential mobility of the glucose transporters in the hamster cells appeared to be related to glycosylation differences of the glucose transporters. Although normal human and hamster cell lines exhibited significant increases in insulin-stimulated sugar transport (P < 0.05), the two respective respiration-deficient cell lines exhibited no significant increases in insulin-stimulated sugar transport (P > 0.05). Additionally, the expression of the GLUT 1 mRNA in the human WG750 mutant cells was elevated when compared with GLUT 1 mRNA in normal cells. Insulin exposure significantly increased GLUT 1 mRNA in human cells (P < 0.05). No differences in the GLUT 1 mRNA were observed between both hamster cell lines. Thus, both respiration-deficient cell lines are insulin resistant (i.e., regarding their insulin-stimulated sugar transport). The respiration-deficient mutation results in an increased sugar transport in the human and hamster cells; however, the human cells adapt to the mutation by increasing their levels of GLUT 1 mRNA and eventually membrane-located glucose transporters. On the other hand, the hamster cells adapt by apparently modifying their glucose transporters' intrinsic activity via glycosylation. We feel that these cell systems can be effective models to study the multiple factors involved in sugar transport regulation in vertebrate cells.

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