A transcriptionally active estrogen receptor mutant is a novel type of dominant negative inhibitor of estrogen action.

We have characterized a human estrogen receptor (ER) mutant, V364E, which has a single amino acid substitution in its hormone-binding domain. This ER mutant is fully active or even superactive at saturating levels of estradiol (10(-8) M E2) yet has the capacity to act as a strong dominant negative inhibitor of the wild type ER. In transient transfection assays using ER-negative Chinese hamster ovary (CHO) cells and two different estrogen response element (ERE)-containing promoter reporter genes, V364E treated with 10(-8) M E2 exhibited approximately 250% and 100% of the activity of the wild type ER with these two promoter contexts, respectively. Despite the high activity of V364E when present alone in cells, coexpression of both V364E and wild type ER causes a significant decrease in overall ER-mediated transcriptional activity. On the TATA promoter, where V364E was more inhibitory, estrogen-stimulated activity was reduced by approximately 50% at a 1:1 ratio of mutant to wild type ER expression vector, and at a 10:1 ratio, 75% of ER activity was inhibited. V364E was expressed at lower levels than wild type ER and has a approximately 40-fold lower affinity for E2 compared with wild type ER. In promoter interference assays, V364E exhibited a strict dependence upon E2 for binding to an ERE. Surprisingly, even when V364E was unable to bind to ERE DNA (i.e. either at low E2 concentration or by mutation of its DNA-binding domain), this mutant retained full dominant negative activity. This highly active ER mutant is, thus, able to repress ER-mediated transcription when the mutant and wild type ER are present together in cells, even without DNA binding. Since competition for ERE binding and the formation of inactive heterodimers cannot fully account for the dominant negative activity of V364E, it is probable that altered interactions with proteins important in ER-mediated transcription play a key role in the repression of transcription by V364E. The properties and probable mechanism of action of V364E distinguish it from other previously described dominant negative inhibitors, in which competition for cis-acting DNA elements by transcriptionally inactive receptors played a large role in the resultant dominant negative phenotype.

Repression of endogenous estrogen receptor activity in MCF-7 human breast cancer cells by dominant negative estrogen receptors.

We have investigated the ability of several transcriptionally inactive estrogen receptor (ER) mutants to block endogenous ER-mediated transcription in MCF-7 human breast cancer cells. In transient transfections of MCF-7 cells, two of the mutants, a frame-shifted ER (S554fs) and a point-mutated ER (L540Q), strongly inhibit the ability of endogenous wild-type ER to activate transcription of estrogen-regulated reporter plasmids. A third mutant, ER1-530, which is missing 65 residues from its carboxy-terminus, is a weaker repressor of estradiol-stimulated transcription. When an estrogen response element (ERE)-thymidine kinase-chloramphenicol acetyltransferase reporter gene is used, S554fs, L540Q, and ER1-530 suppress the transcriptional activity of endogenous MCF-7 ER by 87%, 97%, and 62%, respectively. The magnitude of dominant negative repression is promoter specific; when an ERE-pS2-chloramphenicol acetyltransferase reporter is employed, inhibition of endogenous ER activity by equivalent amounts of S554fs, L540Q, and ER1-530 ranges from 85-97%. Dose-response studies show the S554fs mutant to be the most potent of the three ER mutants as a repressor of estrogen action in these cells. In addition, elevated levels of intracellular cAMP, achieved by the addition of 3-isobutyl-1-methylxanthine plus cholera toxin to cells, fail to compromise the effectiveness of these mutants as dominant negative ERs despite the cAMP-enhanced transcriptional activity of ER. The mutants are also powerful repressors of the agonist activity of trans-hydroxytamoxifen-stimulated ER transcription. The dominant negative activity of the three mutants is lost when the A/B domain of these receptors is deleted, implying an important role for this N-terminal region of the ER in the ability of these mutants to inhibit endogenous wild-type ER activity. All in all, the data suggest that S554fs in particular is a reasonable candidate for studies designed to use a dominant negative ER to inhibit the estrogen- and tamoxifen-stimulated growth of human breast cancer cells.

Activation of transcriptionally inactive human estrogen receptors by cyclic adenosine 3',5'-monophosphate and ligands including antiestrogens.

We show that some transcriptionally inactive human estrogen receptor (ER) mutants can be activated by 17 beta-estradiol (E2), and sometimes by antiestrogens, in the presence of elevated levels of intracellular cAMP. ER-deficient Chinese hamster ovary or 3T3 mouse fibroblast cells were transfected with mutant ERs (the point mutant L540Q, the frameshift mutant S554fs, or the carboxy-terminal truncated receptor ER1-530) and various estrogen response element-containing reporter genes. Individual treatments with E2, the antiestrogens trans-hydroxytamoxifen and ICI 164,384, or with 3-isobutyl-1-methyl-xanthine plus cholera toxin (IBMX plus CT) which raise intracellular cAMP, generally do not activate the mutant receptors. However, cotreatment with IBMX/CT and one of the three ligands (E2, trans-hydroxytamoxifen, or ICI164,384) results in the unexpected recovery of strong activation of the L540Q or S554fs receptors, the magnitude of which is dependent upon promoter- and cell-contexts. Unlike L540Q and S554fs, the transcriptionally inactive ER1-530 is not activated by any combination of ligands and IBMX/CT. These data demonstrate that some ER mutants that form transcriptionally nonproductive ER-E2 complexes can be successfully activated by the combination of an agonist or antagonist ligand and an agent thought to act via phosphorylation pathways. Also highlighted is the promoter- and cell-specific nature of the transcriptional response to different ligand-ER complexes. Lastly, the enhanced transcriptional activity of wild type ER and some ER mutants in the presence of antiestrogens and elevated intracellular cAMP may provide a partial explanation of the ability of some estrogen-dependent human breast tumors to resist antiestrogen therapies currently employed.

Hormone binding and transcription activation by estrogen receptors: analyses using mammalian and yeast systems.

We have used affinity labeling, site-directed mutagenesis and regional chemical mutagenesis in order to determine regions of the human estrogen receptor (ER) important in hormone binding, ligand discrimination between estrogens and antiestrogens, and transcriptional activation. Affinity labeling studies with the antiestrogen, tamoxifen aziridine and the estrogen, ketononestrol aziridine have identified cysteine 530 in the ER hormone binding domain as the primary site of labeling. In the absence of a cysteine at 530 (i.e. C530 mutant), C381 becomes the site of estrogen-compatible tamoxifen aziridine labeling. Hence these two residues, although far apart in the primary linear sequence of the ER protein, must be close in the three-dimensional structure of the protein, in the ER ligand binding pocket, so that the ligand can reach either site. Site-directed mutagenesis of selected residues in the ER and region-specific chemical mutagenesis of the ER hormone binding domain with initial phenotypic screening in yeast have enabled the identification of a region near C530 important in discrimination between estrogens and antiestrogens and of other residues important in hormone-dependent transcriptional activation. Some ER mutants with alterations in the carboxy-terminal portion of the hormone binding domain are transcriptionally inactive yet bind hormone and also function as potent dominant negative ERs, suppressing the activity of wild-type ER at low concentrations. These studies reveal a separation of the hormone binding and transcription activation functions of the ER. They are also beginning to provide a more detailed picture of the ER hormone binding domain and amino acids important in ligand binding and discrimination between different categories of agonist and antagonist ligands. Such information will be important in the design of maximally effective antiestrogens. In addition, since there is now substantial evidence for a mixture of wild-type and variant ERs in breast cancers, our studies should provide insight about the bioactivities of these variant receptors and their roles in modulating the activity of wild type ER, and should lead to a better understanding of the possible role of variant receptors in altered response or resistance to antiestrogen and endocrine therapy in breast cancer. In addition, some dominant negative receptors may prove useful in examining ER mechanisms of action and in suppressing the estrogen-dependent growth of breast cancer cells.

Powerful dominant negative mutants of the human estrogen receptor.

We have identified and characterized three human estrogen receptor (ER) mutants, which, at low concentrations, are capable of blocking the intracellular activity of wild type ER. The mutants, a truncated ER (ER1-530), a point mutant (L540Q), and a frameshift (S554fs), were generated by random chemical mutagenesis of the ER hormone binding domain and screened first for low activity in a yeast selection system. In transient co-transfection assays using ER-deficient Chinese hamster ovary cells, all three mutants exhibited less than 10% of the transcription activation activity of wild type ER, and when co-expressed with wild type ER, each of the mutants effectively suppressed the ability of wild type ER to activate transcription of an estrogen-regulated reporter plasmid. When equal amounts of plasmid encoding the ER mutants and wild type ER were used, S554fs, ER1-530, and L540Q suppressed the activity of wild type ER by 80, 55, and 75%, respectively. At a ratio of 1 part S554fs to 10 parts wild type ER, transcription was still inhibited by 40%. Western blot analysis showed that all three mutants were expressed at approximately the same level as wild type ER. Suppression of transcription was specific for ER, since the mutants did not inhibit progesterone receptor-mediated transcription. Not all mutations leading to inactive ER confer the dominant negative phenotype, as five ER mutants rendered transcriptionally inactive by point mutations between residues 516 and 524 of the ER hormone binding domain were poor inhibitors of wild type ER activity. Binding studies showed that the L540Q and S554fs dominant negative mutants bound 17 beta-estradiol with wild type affinity (Kd = 0.3-0.5 nM), whereas ER1-530 exhibited a 15-fold reduction in affinity for estradiol. The three dominant negative ERs showed significant ability to interact with the estrogen response element (ERE) in promoter interference assays, but ER1-530 and S554fs displayed little or no binding to the ERE in gel mobility shift assays where higher affinity for the DNA may be required for the receptor-ERE complex to remain associated during the electrophoresis. These data support the idea that, in all three mutants, it is loss of function of the COOH-terminal transactivation domain which leads to the dominant negative phenotype. S554fs, a powerful dominant negative mutant, is a good candidate for further studies aimed at suppressing the estrogen-dependent growth of human breast cancer cells.

William L. McGuire Memorial Symposium. Estrogen receptors: ligand discrimination and antiestrogen action.

We have used affinity labeling, site-directed mutagenesis and regional chemical mutagenesis in order to determine regions of the estrogen receptor (ER) important in hormone binding, ligand discrimination between estrogens and antiestrogens, and transcriptional activation. Affinity labelling studies with the antiestrogen, tamoxifen aziridine and the estrogen, ketononestrol aziridine have identified cysteine 530 in the ER hormone binding domain as the primary site of labeling. In the absence of a cysteine at 530 (i.e. Cys530A1a mutant), C381 becomes the site of estrogen-compatible tamoxifen aziridine labeling. Hence these two residues, although far apart in the primary linear sequence of the ER protein, must be close in the three-dimensional structure of the protein, in the ER ligand binding pocket, so that the ligand can reach either site. Site-directed and region-specific chemical mutagenesis have identified a region around C530 important in discrimination between estrogens and antiestrogens, and other mutants have allowed identification of residues important in hormone-dependent transcriptional activation. Some transcriptionally inactive ER mutants also function as potent dominant negative ERs, suppressing the activity of wild-type ERs at low concentrations. These studies are beginning to provide a more detailed picture of the ER hormone binding domain and amino acids important in ligand binding and discrimination between different categories of agonist and antagonist ligands. Such information will be important in the design of maximally effective antiestrogens. In addition, since there is now substantial evidence for a mixture of wild-type and variant ERs in breast cancers, our studies should provide insight about the bioactivities of these variant receptors and their roles in modulating the activity of wild type ER, and should lead to a better understanding of the possible role of variant receptors in altered response or resistance to antiestrogen and endocrine therapy in breast cancer.