Le Goff P, Montano M M, Schodin D J, Katzenellenbogen B S
Department of Physiology and Biophysics, University of Illinois, Urbana 61801.
J Biol Chem. 1994 Feb 11;269(6):4458-66.
We have used a transient transfection system with a cytomegalovirus-based vector expressing high levels of biologically active human estrogen receptor (ER) in COS-1 cells to study the phosphorylation of human ER and to identify major hormone-regulated phosphorylation sites. The features of phosphorylation of the wild-type ER were very similar to those previously observed for the endogenous ER in uterine cells: The ER exhibited a basal level of phosphorylation which was increased approximately 3-4-fold by estrogen (estradiol) and by antiestrogens (hydroxytamoxifen and ICI164,384), and phosphorylation was increased to an almost similar extent by activation of either protein kinase A or C signal transduction pathways with cholera toxin plus isobutyl methylxanthine (CT+IBMX) or phorbol ester 12-O-tetradecanoylphorbol-13-acetate (TPA), respectively. Phosphoamino acid analysis revealed that the phosphorylation occurred exclusively on serine residues in all cases. Tryptic phosphopeptide analysis of ER, using a two-dimensional peptide mapping procedure, revealed similar patterns for ER in cells treated with estradiol, antiestrogens or TPA; with CT+IBMX treatment, the same phosphopeptides were seen, but the relative phosphorylation of the different ER phosphotryptic peptides differed. In ER deleted of the NH2-terminal A and B (A/B) domains, estrogen and antiestrogen-stimulated phosphorylations were abolished, while the phosphorylation induced by CT+IBMX was maintained. This suggests that sites of phosphorylation enhanced by estradiol and antiestrogen, but not those induced by CT+IBMX, are located in the A/B domain. These results were further confirmed by comparing the tryptic phosphopeptide patterns of wild-type and A/B-deleted receptor upon estradiol and CT+IBMX treatments, and then by site-directed mutagenesis, by substituting alanines for the serine residues in the A/B domain (Ser104, Ser106, Ser118, Ser154, and Ser167) involved in known protein kinase consensus sequences. Comparison of the tryptic phosphopeptide patterns of wild-type ER and these mutant ERs allowed us to identify serine 104 and/or serine 106 and serine 118, all three being part of a serine-proline motif, the preferred substrate of proline-directed protein kinase, as major ER phosphorylation sites. When tested with two estrogen-responsive reporter gene constructs in several cell types, the mutant S104A, S106A, S118A showed a approximately 40% reduction in transactivation activity in response to E2, while the mutants S118A and S104A, S106A alone showed a approximately 15% decrease in transactivation. Our studies identify several serines in the NH2-terminal portion of the human ER as being major hormone-regulated phosphorylation sites.(ABSTRACT TRUNCATED AT 250 WORDS)
我们利用一种基于巨细胞病毒的载体的瞬时转染系统,该载体在COS-1细胞中能高水平表达具有生物活性的人雌激素受体(ER),以研究人ER的磷酸化作用并确定主要的激素调节磷酸化位点。野生型ER的磷酸化特征与先前在子宫细胞中观察到的内源性ER的特征非常相似:ER表现出基础磷酸化水平,雌激素(雌二醇)和抗雌激素(羟基他莫昔芬和ICI164,384)可使其增加约3至4倍,通过分别用霍乱毒素加异丁基甲基黄嘌呤(CT + IBMX)或佛波酯12-O-十四酰佛波醇-13-乙酸酯(TPA)激活蛋白激酶A或C信号转导途径,磷酸化也增加到几乎相似的程度。磷酸氨基酸分析表明,在所有情况下磷酸化仅发生在丝氨酸残基上。使用二维肽图谱程序对ER进行胰蛋白酶磷酸肽分析,结果显示在用雌二醇、抗雌激素或TPA处理的细胞中ER的图谱相似;用CT + IBMX处理时,可见相同的磷酸肽,但不同ER胰蛋白酶磷酸肽的相对磷酸化情况有所不同。在缺失NH2末端A和B(A/B)结构域的ER中,雌激素和抗雌激素刺激的磷酸化作用被消除,而CT + IBMX诱导的磷酸化作用得以维持。这表明,雌二醇和抗雌激素增强的磷酸化位点,而非CT + IBMX诱导的位点,位于A/B结构域。通过比较野生型和A/B缺失型受体在雌二醇和CT + IBMX处理后的胰蛋白酶磷酸肽图谱,然后通过定点诱变,将A/B结构域中参与已知蛋白激酶共有序列的丝氨酸残基(Ser104、Ser106、Ser118、Ser154和Ser167)替换为丙氨酸,进一步证实了这些结果。比较野生型ER和这些突变型ER的胰蛋白酶磷酸肽图谱,使我们能够确定丝氨酸104和/或丝氨酸106以及丝氨酸118,这三个丝氨酸均为丝氨酸-脯氨酸基序的一部分,是脯氨酸定向蛋白激酶的优选底物,为主要的ER磷酸化位点。当在几种细胞类型中用两种雌激素反应性报告基因构建体进行测试时,突变体S104A、S106A、S118A对E2的反式激活活性降低约40%,而突变体S118A和单独的S104A、S106A反式激活活性降低约15%。我们的研究确定了人ER NH2末端部分的几个丝氨酸为主要的激素调节磷酸化位点。(摘要截短至250字)
