Mamula P W, McDonald A R, Brunetti A, Okabayashi Y, Wong K Y, Maddux B A, Logsdon C, Goldfine I D
Division of Diabetes and Endocrine Research, Mount Zion Hospital and Medical Center, San Francisco, CA 94120.
Diabetes Care. 1990 Mar;13(3):288-301. doi: 10.2337/diacare.13.3.288.
Insulin regulates cell function by first binding to the insulin receptor (IR) localized on the cell surface. With the cloning of IR cDNA and the IR-gene promoter, the regulation of the IR gene during differentiation and by various hormones can be studied. Muscle is a major target tissue for insulin action. BC3H1 cells, a mouse muscle cell line in culture, are a model cell type for studying insulin action. Differentiation in these cells results in a 5- to 10-fold increase in IR binding and a 5- to 10-fold increase in IR content. Studies of IR mRNA by Northern and slot-blot analyses reveal a 10-fold increase in IR mRNA after differentiation. These studies indicate that there is a selective increase in IR-gene expression during muscle differentiation. A similar increase in IR-gene expression is observed for the IR during pancreatic acinar cell differentiation. Glucocorticoids increase IR content in several target tissues. Studies in cultured IM-9 lymphocytes indicate that glucocorticoids induce a 5-fold increase in IR mRNA levels. Studies of IR mRNA half-life indicate that glucocorticoids do not alter IR mRNA stability. When the transcription of the IR is measured by elongation assays, glucocorticoids directly stimulate IR transcription 5- to 10-fold. The effect is detectable within 30 min of glucocorticoid treatment and is maximal within 2 h. Therefore, these studies demonstrate that the IR gene is under the direct regulation of glucocorticoids. Insulin downregulates the IR in various target tissues. Prior studies indicate that this downregulation was partly because of accelerated IR degradation. Studying AR42J pancreatic acinar cells, we also found that insulin accelerates IR degradation. Moreover, in these cells, insulin decreases IR biosynthesis by approximately 50%. Studies of IR mRNA indicate there is a concomitant decrease in IR mRNA levels after insulin treatment. Thus, insulin decreases IR-gene expression. The genomic structure of the IR promoter has been elucidated. Primer extension and nuclease S1 analysis indicate that IR mRNA has multiple start sites. The promoter fragment was ligated to a promoterless "reporter" plasmid containing the bacterial gene chloramphenicol acetyltransferase (CAT). When this plasmid is transfected into cultured cells, CAT activity is detected, indicating promoter activity. Various portions of a genomic fragment were ligated to a promoter to study glucocorticoid regulation of the IR promoter. These studies indicate that IR-gene expression is regulated by differentiation and hormonal agents.(ABSTRACT TRUNCATED AT 400 WORDS)
胰岛素首先与位于细胞表面的胰岛素受体(IR)结合,从而调节细胞功能。随着IR cDNA和IR基因启动子的克隆,可以研究分化过程中以及各种激素对IR基因的调节作用。肌肉是胰岛素作用的主要靶组织。BC3H1细胞是一种培养中的小鼠肌肉细胞系,是研究胰岛素作用的一种模型细胞类型。这些细胞的分化导致IR结合增加5至10倍,IR含量增加5至10倍。通过Northern和狭缝印迹分析对IR mRNA的研究表明,分化后IR mRNA增加了10倍。这些研究表明,在肌肉分化过程中IR基因表达有选择性增加。在胰腺腺泡细胞分化过程中,IR基因表达也有类似的增加。糖皮质激素可增加几种靶组织中的IR含量。对培养的IM-9淋巴细胞的研究表明,糖皮质激素可使IR mRNA水平增加5倍。对IR mRNA半衰期的研究表明,糖皮质激素不会改变IR mRNA的稳定性。当通过延伸测定法测量IR的转录时,糖皮质激素可直接刺激IR转录5至10倍。在糖皮质激素处理后30分钟内即可检测到这种作用,2小时内达到最大值。因此,这些研究表明IR基因受糖皮质激素的直接调节。胰岛素可下调各种靶组织中的IR。先前的研究表明,这种下调部分是由于IR降解加速。在研究AR42J胰腺腺泡细胞时,我们还发现胰岛素会加速IR降解。此外,在这些细胞中,胰岛素可使IR生物合成减少约50%。对IR mRNA的研究表明,胰岛素处理后IR mRNA水平会随之下降。因此,胰岛素会降低IR基因表达。IR启动子的基因组结构已得到阐明。引物延伸和核酸酶S1分析表明,IR mRNA有多个起始位点。将启动子片段连接到一个无启动子的“报告”质粒上,该质粒含有细菌基因氯霉素乙酰转移酶(CAT)。当将该质粒转染到培养细胞中时,可检测到CAT活性,表明有启动子活性。将基因组片段的不同部分连接到一个启动子上,以研究糖皮质激素对IR启动子的调节作用。这些研究表明,IR基因表达受分化和激素的调节。(摘要截选至400字)
