We show that a number of alkylphenolic compounds, used in a variety of commercial products and found in river water, are estrogenic in fish, birds, and mammals. 4-Octylphenol (OP), 4-nonylphenol, 4-nonylphenoxycarboxylic acid, and 4-nonylphenoldiethoxylate were each capable of stimulating vitellogenin gene expression in trout hepatocytes, gene transcription in transfected cells, and the growth of breast cancer cell lines. The most potent of the chemicals is OP, which was able to stimulate these biological responses to a similar extent as 17 beta-estradiol itself, albeit at a 1000-fold greater concentration. The action of alkylphenols is mediated by the estrogen receptor, as their effects depended on its presence and was blocked by estrogen antagonists. OP, 4-nonylphenol, and 4-nonylphenoxycarboxylic acid appear to possess intrinsic estrogenic activity, because they compete for binding to the estrogen receptor. Moreover, it is likely that they interact with a similar region of the hormone-binding domain as 17 beta-estradiol, because the mutant receptor G-525R, which is defective in estrogen binding, is also insensitive to OP. Like 17 beta-estradiol, OP is capable of stimulating the activity of both transcriptional activation functions, TAF-1 and TAF-2, in the receptor, as judged by analyzing the activity of the wild-type and mutant receptors in transiently transfected cells. The significance of our results will depend to a large extent on the degree of exposure of wildlife and humans to these estrogenic alkylphenolic compounds.
The oestrogen receptor stimulates transcription by means of at least two distinct transcriptional activation domains, TAF‐1 in the N‐terminal domain and TAF‐2 in the hormone binding domain. Here we show that TAF‐2 activity requires a region in the C‐terminus of the hormone binding domain between residues 538 and 552 in the mouse oestrogen receptor which is conserved among many nuclear hormone receptors. Point mutagenesis of conserved hydrophobic and charged residues significantly reduced ligand dependent transcriptional activation but had no effect on steroid or DNA binding. Mutation of the corresponding residues in the glucocorticoid receptor also abolished transcriptional activation. We therefore propose that the conserved region may be essential for ligand dependent transcriptional activation by other members of the nuclear receptor family.
Sewage, a complex mixture of organic and inorganic chemicals, is considered to be a major source of environmental pollution. A random screen of 20 organic man-made chemicals present in liquid effluents revealed that half appeared able to interact with the estradiol receptor. This was demonstrated by their ability to inhibit binding of 17 beta-estradiol to the fish estrogen receptor. Further studies, using mammalian estrogen screens in vitro, revealed that the two phthalate esters butylbenzyl phthalate (BBP) and di-n-butylphthalate (DBP) and a food antioxidant, butylated hydroxyanisole (BHA) were estrogenic; however, they were all less estrogenic than the environmental estrogen octylphenol. Phthalate esters, used in the production of various plastics (including PVC), are among the most common industrial chemicals. Their ubiquity in the environment and tendency to bioconcentrate in animal fat are well known. Neither BBP nor DBP were able to act as antagonists, indicating that, in the presence of endogenous estrogens, their overall effect would be cumulative. Recently, it has been suggested that environmental estrogens may be etiological agents in several human diseases, including disorders of the male reproductive tract and breast and testicular cancers. The current finding that some phthalate compounds and some food additives are weakly estrogenic in vitro, needs to be supported by further studies on their effects in vivo before any conclusions can be made regarding their possible role in the development of these conditions. Images Figure 1. Figure 2. Figure 3. Figure 4.
Nuclear receptors and their coactivators have been shown to function as key regulators of adipose tissue biology. Here we show that a ligand-dependent transcriptional repressor for nuclear receptors plays a crucial role in regulating the balance between energy storage and energy expenditure. Mice devoid of the corepressor protein RIP140 are lean, show resistance to high-fat diet-induced obesity and hepatic steatosis, and have increased oxygen consumption. Although the process of adipogenesis is unaffected, expression of certain lipogenic enzymes is reduced. In contrast, genes involved in energy dissipation and mitochondrial uncoupling, including uncoupling protein 1, are markedly increased. Therefore, the maintenance of energy homeostasis requires the action of a transcriptional repressor in white adipose tissue, and ligand-dependent recruitment of RIP140 to nuclear receptors may provide a therapeutic target in the treatment of obesity and related disorders. E nergy homeostasis is a highly regulated process that requires precise control of food intake and energy expenditure (1). The major and most efficient storage of energy occurs in the form of triglycerides in white adipose tissue (WAT), and it is now clear that the adipocyte itself may act as an endocrine cell such that altered adipocyte function would cause changes in systemic energy balance (2, 3). From adipogenic stores, fatty acids are easily mobilized during periods of energy restriction or increased physical activity to provide enough fuel for energy synthesis in the form of ATP. In addition, energy is dissipated by generating heat in brown adipose tissue (BAT) and skeletal muscles by regulating the uncoupling of ATP production from respiration. Many of these metabolic processes are controlled in part by nuclear receptors (4, 5), including peroxisome proliferatoractivated receptors (PPARs) (6, 7), thyroid hormone receptor (8, 9), estrogen receptor ␣ (ER␣) (10, 11), and ER-related receptor ␣ (ERR␣) (12). The best characterized of these are the PPARs, with PPAR␥ and PPAR␣ playing an essential role in adipogenesis (13-16) and in thermogenesis and fatty acid oxidation (17-19), respectively, whereas recent studies have implicated a role for PPAR␦ in lipid homeostasis (20).Nuclear receptors stimulate target gene transcription by recruiting coactivators that are required to remodel chromatin and facilitate the assembly of the basal transcription machinery (21). The key coactivator in metabolic processes is the PPAR␥ coactivator 1␣ (PGC-1␣) (22-25), which was initially shown to promote adaptive thermogenesis in BAT and which has emerged as a target for integrating signals in the regulation of specific metabolic programs in other tissues, including muscle and liver. More recently, the related coactivator PGC-1 (26, 27) has been implicated in the regulation of energy expenditure as a potential coactivator for ERR␣ (28). In addition, the p160 family of coactivators has also been found to control energy balance in adipose tissue. For instance, SRC1, in associatio...
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