Small ubiquitin-like modifier (SUMO) modification mediates function of the inhibitory domains of developmental regulators FOXC1 and FOXC2.

FOXC1 and FOXC2 are forkhead transcription factors that play essential roles during development and physiology. Despite their critical role, the mechanisms that regulate the function of these factors remain poorly understood. We have identified conserved motifs within a previously defined N-terminal negative regulatory region of FOXC1/C2 that conforms to the definition of synergy control or SC motifs. Because such motifs inhibit the activity of transcription factors by serving as sites of post-translational modification by small ubiquitin-like modifier (SUMO), we have examined whether FOXC1/C2 are targets of SUMOylation and probed the functional significance of this modification. We find that endogenous FOXC1 forms modified by SUMO2/3 can be detected. Moreover, in cell culture, all three SUMO isoforms are readily conjugated to FOXC1 and FOXC2. The modification can be reconstituted in vitro with purified components and can be reversed in vitro by treatment with the SUMO protease SENP2. SUMOylation of FOXC1 and FOXC2 occurs primarily on one consensus synergy control motif with minor contributions of a second, more degenerate site. Notably, although FOXC1 is also phosphorylated at multiple sites, disruption of sites immediately downstream of the SC motifs does not influence SUMOylation. Consistent with a negative functional role, SUMOylation-deficient mutants displayed higher transcriptional activity when compared with wild type forms despite comparable protein levels and subcellular localization. Thus, the findings demonstrate that SC motifs mediate the inhibitory function of this region by serving as sites for SUMOylation and reveal a novel mechanism for acute and reversible regulation of FOXC1/C2 function.

Distinct molecular conformations of the estrogen receptor alpha complex exploited by environmental estrogens.

We have advanced the view that estrogens activate the estrogen receptor (ER) alpha complex differently. A group of planar (estradiol, genistein, and coumestrol) and nonplanar (methoxychlor and its mono- and didemethylated phenolic metabolites) environmental estrogens, which are all full estrogens in MCF-7 breast cancer cell proliferation assays, was shown to segregate discretely into planar and nonplanar groups. These groups were delineated using a novel assay of mutant ER cDNAs stably transfected into MDA-MB-231 cells and the activation of the transforming growth factor alpha target gene in situ that putatively describes the external shape of the ER complex. Planar compounds activate estrogen action through the two traditional activation functions (AFs), AF1 and AF2, in the ER. In contrast, nonplanar compounds can activate estrogen action through AF1 and the amino acids Asp-351 and Asp-538, which are exposed when helix 12 silences AF2. The observation that class I (planar) and class II (nonplanar) compounds have different mechanisms of estrogen action may have important implications for tissue selective modulation of the ER.

Chemical communication threatened by endocrine-disrupting chemicals.

Communication on a cellular level--defined as chemical signaling, sensing, and response--is an essential and universal component of all living organisms and the framework that unites all ecosystems. Evolutionarily conserved signaling "webs," existing both within an organism and between organisms, rely on efficient and accurate interpretation of chemical signals by receptors. Therefore, endocrine-disrupting chemicals (EDCs), which have been shown to disrupt hormone signaling in laboratory animals and exposed wildlife, may have broader implications for disrupting signaling webs that have yet to be identified as possible targets. In this article, I explore common evolutionary themes of chemical signaling (e.g., estrogen signaling in vertebrates and phytoestrogen signaling from plants to symbiotic soil bacteria) and show that such signaling systems are targets of disruption by EDCs. Recent evolutionary phylogenetic data have shown that the estrogen receptor (ER) is the ancestral receptor from which all other steroid receptors have evolved. In addition to binding endogenous estrogens, ERs also bind phytoestrogens, an ability shared in common with nodulation D protein (NodD) receptors found in Rhizobium soil bacteria. Recent data have shown that many of the same synthetic and natural environmental chemicals that disrupt endocrine signaling in vertebrates also disrupt phytoestrogen-NodD receptor signaling in soil bacteria, which is necessary for nitrogen-fixing symbiosis. Bacteria-plant symbiosis is an unexpected target of EDCs, and other unexpected nontarget species may also be vulnerable to EDCs found in the environment.

Phytoestrogen signaling and symbiotic gene activation are disrupted by endocrine-disrupting chemicals.

Some organochlorine pesticides and other synthetic chemicals mimic hormones in representatives of each vertebrate class, including mammals, reptiles, amphibians, birds, and fish. These compounds are called endocrine-disrupting chemicals (EDCs). Similarly, hormonelike signaling has also been observed when vertebrates are exposed to plant chemicals called phytoestrogens. Previous research has shown the mechanism of action for EDCs and phytoestrogens is as unintended ligands for the estrogen receptor (ER). Although pesticides have been synthesized to deter insects and weeds, plants produce phytoestrogens to deter herbivores, as attractant cues for insects, and as recruitment signals for symbiotic soil bacteria. Our data present the first evidence that some of the same organochlorine pesticides and EDCs known to disrupt endocrine signaling through ERs in exposed wildlife and humans also disrupt the phytoestrogen signaling that leguminous plants use to recruit Sinorhizobium meliloti soil bacteria for symbiotic nitrogen fixation. Here we report that a variety of EDCs and pesticides commonly found in agricultural soils interfere with the symbiotic signaling necessary for nitrogen fixation, suggesting that the principles underlying endocrine disruption may have more widespread biological and ecological importance than had once been thought.

Inter-laboratory comparison of a yeast bioassay for the determination of estrogenic activity in biological samples.

An inter-laboratory exercise was performed with a yeast estrogen bioassay, based on the expression of yeast enhanced green fluorescent protein (yEGFP), for the determination of estrogenic activity in extracts of calf urine samples. Urine samples were spiked with 1 and 5 ngmL(-1) 17beta-estradiol and 17alpha-ethynylestradiol, 10 and 50 ngmL(-1) mestranol, and 100 ngmL(-1) testosterone and progesterone. Sample extracts of blank and spiked urine samples were prepared at our laboratory and sent to seven laboratories together with a reagent blank, a DMSO blank, and eight 17beta-estradiol stock solutions in DMSO ranging in concentration from 0 to 545 ngmL(-1). Sample extracts and standards were coded and tested blindly. A decision limit (CCalpha) was determined based on the response of seven blank urine samples. Signals of the negative controls, e.g. urine samples spiked with 100 ngmL(-1) testosterone or progesterone, were all below the determined CCalpha and were thus screened as compliant. Positive controls, i.e. the urine samples spiked at two levels with 17beta-estradiol, 17alpha-ethynylestradiol and mestranol, were almost all screened as suspect, i.e. gave signals above the determined CCalpha. Determined EC(50) values calculated from the 17beta-estradiol dose-response curves obtained by the seven laboratories ranged from 0.59 to 0.95 nM.

Detecting ligands and dissecting nuclear receptor-signaling pathways using recombinant strains of the yeast Saccharomyces cerevisiae.

This is a general protocol for the identification of natural and xenobiotic ligands of metazoan nuclear receptors (NRs) expressed in yeast. Yeast engineered to express an NR and a response element-driven reporter gene provide a system to detect and quantify ligand-dependent transcriptional activity. Such assays allow researchers to measure different types of ligands and determine dose-dependent activation of NRs. This methodology can also be used to examine the components of signal transduction pathways when conducted with mutant or engineered yeast strains expressing additional proteins or having alternate DNA response elements. This assay typically takes 2-3 d to complete, but most of this time entails cell growth rather than 'hands on' time.

An evolvable oestrogen receptor activity sensor: development of a modular system for integrating multiple genes into the yeast genome.

To study a gene interaction network, we developed a gene-targeting strategy that allows efficient and stable genomic integration of multiple genetic constructs at distinct target loci in the yeast genome. This gene-targeting strategy uses a modular plasmid with a recyclable selectable marker and a multiple cloning site into which the gene of interest is cloned, flanked by two long regions of homology to the target genomic locus that are generated using adaptamer primers. We used this strategy to integrate into a single yeast strain components of the oestrogen receptor (ER) signalling network, comprising the human ERalpha and three reporter genes driven by oestrogen response elements (EREs). The engineered strain contains multiple reporters of ligand-dependent receptor signalling, providing sensitive, reproducible, rapid, low-cost quantitative assays of ERalpha activity in order to screen potential receptor agonists. Further, because two of the ERE-driven reporter genes are required for growth in deficient media, the strain's growth rate-and therefore its fitness-depends on ligand-induced ERalpha activity. This evolvable oestrogen receptor activity sensor (EERAS) can therefore provide the foundation of a long-term experimental evolution strategy to elucidate ER structure-function relations and ligand-receptor evolution.

Pesticides reduce symbiotic efficiency of nitrogen-fixing rhizobia and host plants.

Unprecedented agricultural intensification and increased crop yield will be necessary to feed the burgeoning world population, whose global food demand is projected to double in the next 50 years. Although grain production has doubled in the past four decades, largely because of the widespread use of synthetic nitrogenous fertilizers, pesticides, and irrigation promoted by the "Green Revolution," this rate of increased agricultural output is unsustainable because of declining crop yields and environmental impacts of modern agricultural practices. The last 20 years have seen diminishing returns in crop yield in response to increased application of fertilizers, which cannot be completely explained by current ecological models. A common strategy to reduce dependence on nitrogenous fertilizers is the production of leguminous crops, which fix atmospheric nitrogen via symbiosis with nitrogen-fixing rhizobia bacteria, in rotation with nonleguminous crops. Here we show previously undescribed in vivo evidence that a subset of organochlorine pesticides, agrichemicals, and environmental contaminants induces a symbiotic phenotype of inhibited or delayed recruitment of rhizobia bacteria to host plant roots, fewer root nodules produced, lower rates of nitrogenase activity, and a reduction in overall plant yield at time of harvest. The environmental consequences of synthetic chemicals compromising symbiotic nitrogen fixation are increased dependence on synthetic nitrogenous fertilizer, reduced soil fertility, and unsustainable long-term crop yields.

Non-traditional targets of endocrine disrupting chemicals: the roots of hormone signaling.

The topic of endocrine disruption and the broad range of physiological effects caused by endocrine disrupting chemicals (EDCs) can only be meaningfully framed within an ecological and evolutionary context. Environmental pollutants and EDCs operate by disrupting the "chemical communication" that coordinates signaling within an organism. Here we discuss how EDCs are also able to disrupt the chemical communication between plants and soil bacteria necessary for initiating nitrogen-fixing symbiosis. We also examine, through examples of pollutant-related impacts on a wide range of invertebrates, the need for identifying emerging targets of EDCs. We suggest broadening the defined field of endocrine disruption to encompass the effects of synthetic chemicals that interfere with signaling and communication, not only within an organism, but also between organisms and linking ecosystems. The ecological consequences of failing to recognize novel targets of chemical pollutants and EDCs may be a net loss of biological diversity and a further imbalance of the global nitrogen cycle.