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 phytoestrogen /phy·to·es·tro·gen/ (-es´tro-jen) any of a group of weakly estrogenic, nonsteroidal compounds widely occurring in plants. phy·to·es·tro·gen n. signaling from plants to symbiotic symbiotic /sym·bi·ot·ic/ (sim?bi-ot´ik) associated in symbiosis; living together. sym·bi·ot·ic adj. Of, resembling, or relating to symbiosis. soil bacteria) and show that such signaling systems are targets of disruption by EDCs. Recent evolutionary phylogenetic phy·lo·ge·net·ic adj. 1. Of or relating to phylogeny or phylogenetics. 2. Relating to or based on evolutionary development or history. data have shown that the estrogen receptor estrogen receptor A protein of a superfamily of nuclear receptors for small hydrophilic ligands–eg, steroid hormones, thyroid hormone, vitamin D, retinoids; the presence of ERs in breast CA generally is associated with a better prognosis, as they respond to (ER) is the ancestral receptor from which all other steroid receptors have evolved. In addition to binding endogenous estrogens Estrogens Hormones produced by the ovaries, the female sex glands. Mentioned in: Acne, Polycystic Ovary Syndrome estrogens (es´trōjenz), n. , ERs also bind phytoestrogens Phytoestrogens Compounds found in plants that can mimic the effects of estrogen in the body. Mentioned in: Premenstrual Syndrome phytoestrogens, n.pl plant-derived estrogen analogs. , an ability shared in common with nodulation nod·u·la·tion n. The formation or presence of nodules. nodulation the formation of or presence of nodules. D protein (NodD) receptors found in Rhizobium rhi·zo·bi·um n. pl. rhi·zo·bi·a Any of various nitrogen-fixing bacteria of the genus Rhizobium that form nodules on the roots of leguminous plants, such as clover and beans. 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 symbiosis (sĭmbēō`sĭs), the habitual living together of organisms of different species. The term is usually restricted to a dependent relationship that is beneficial to both participants (also called mutualism) but may be extended to . Bacteria-plant symbiosis is an unexpected target of EDCs, and other unexpected nontarget non·tar·get adj. Not being the target, as of an agent or weapon: effects of radiotherapy on nontarget cells. species may also be vulnerable to EDCs found in the environment. Key words: convergent evolution convergent evolution n. See convergence. , ecosystem, endocrine-disrupting chemicals, endocrine disruption, environmental signaling, estrogen receptor, nitrogen fixation, Rhizobium, symbiosis. Environ Health Perspect 112:648-653 (2004). doi:10.1289/ehp.6455 available via http://dx.doi.org/[Online 29 January 2004] ********** Chemical Communication via Signaling Chemical communication is a common means of endogenous and exogenous signaling for countless species. The endocrine system endocrine system (ĕn`dəkrĭn), body control system composed of a group of glands that maintain a stable internal environment by producing chemical regulatory substances called hormones. of vertebrates consists of an intricate web of agonistic agonistic /ag·o·nis·tic/ (ag?o-nis´tik) pertaining to a struggle or competition; as an agonistic muscle, counteracted by an antagonistic muscle. as well as antagonistic hormone signals, which control sexual development and reproduction (McLachlan 2001). For example, circulating hormones such as 17[beta]-estradiol ([E.sub.2]) control a variety of cellular processes, including developmental cues, differentiation events, and growth in organs such as breast, ovary ovary, ductless gland of the female in which the ova (female reproductive cells) are produced. In vertebrate animals the ovary also secretes the sex hormones estrogen and progesterone, which control the development of the sexual organs and the secondary sexual , and uterus. The timing and concentration of estrogen signaling determine sexual maturity, ovulation ovulation /ovu·la·tion/ (ov?u-la´shun) the discharge of a secondary oocyte from a graafian follicle.ov´ulatory o·vu·la·tion n. The discharge of an ovum from the ovary. , and pregnancy. In much the same way, a multitude of organisms rely on chemical cues for development and differentiation. For example, some insects and crustaceans rely on ecdysteroids to signal molting molting, periodical shedding and renewal of the outer skin, exoskeleton, fur, or feathers of an animal. In most animals the process is triggered by secretions of the thyroid and pituitary glands. and growth (Oberdorster et al. 2001), and the slime mold Dictyostelium relies on a chlorinated chlorinated /chlo·ri·nat·ed/ (klor´i-nat?ed) treated or charged with chlorine. chlorinated charged with chlorine. chlorinated acids some, e.g. alkyl alkyl /al·kyl/ (al´k'l) the monovalent radical formed when an aliphatic hydrocarbon loses one hydrogen atom. al·kyl n. phenone called DIF-1 to signal individual cells to differentiate into a multicellular mul·ti·cel·lu·lar adj. Having or consisting of many cells. mul  ti·cel sporulating stalk (Kay 1998;
Town et al. 1976).Plants produce versatile chemical signals, called phytochemicals or phytoestrogens, which serve both as endogenous signals, triggering color and scent production within the plant, and exogenous signals secreted for communication with other organisms, such as to inhibit sexual reproduction sexual reproduction n. Reproduction by the union of male and female gametes to form a zygote. Also called syngenesis. of predatory herbivores (Wynne-Edwards 2001). Leguminous le·gu·mi·nous adj. 1. Of, belonging to, or characteristic of the family Leguminosae, which includes peas, beans, clover, alfalfa, and other plants. 2. Resembling a legume. plants (soybeans, clover, and alfalfa alfalfa (ălfăl`fə) or lucern (l  sûn`), perennial leguminous plant (Medicago sativa ) secrete phytoestrogens into the
soil as recruitment signals for symbiotic mycorrhizal fungi and
Rhizobium soil bacteria, which both provide selective growth advantages
to the host plant, including increased water/phosphate availability and
nitrogenous nitrogenous /ni·trog·e·nous/ (ni-troj´e-nus) containing nitrogen. ni·trog·e·nous adj. Relating to or containing nitrogen. nitrogenous containing nitrogen. fertilizer, respectively (Baker 1998; Kuiper et al. 1997; Peters et al. 1986). Although phytoestrogens serve specific signaling functions between the plants that produce them and insects, fungi, and bacteria, many chemical signals, including the fungal agent zearalenone and the phytoestrogens genistein and luteolin, are often "misinterpreted" as estrogenic signals in nontarget organisms such as vertebrates. For chemical communication to occur within or between organisms, a receptor must have affinity for specific chemical ligands or signals, and this recognition must initiate a response. In fact, a wide variety of natural and synthetic chemicals exist in the environment that mimic hormones and disrupt endocrine signaling in vertebrates through interaction with various nuclear receptors and signal transducer proteins, including the estrogen receptor (ER), orphan receptors, and the thyroid receptor (Cheek et al. 1998; Crump et al. 2002; Ishihara et al. 2003; McLachlan 2001; Moriyama et al. 2002; Takeshita et al. 2001). Some flavonoid phytoestrogens are able to bind ER-[alpha] and ER-[beta] and act as weak agonists (Collins-Burow et al. 2000) that compete with endogenous [E.sub.2] for ER binding and activation of estrogen-responsive genes (Blair et al. 2000; Kuiper et al. 1997). Despite their ability to bind these receptors, phytoestrogens exhibit only a fraction ([10.sup.-2]-[10.sup.-3]) of the estrogenic activity of [E.sub.2] (Collins-Burow et al. 2000). Nevertheless, the most active phytoestrogens found in plants have been shown to induce breast cancer cell proliferation in vitro in vitro /in vi·tro/ (in ve´tro) [L.] within a glass; observable in a test tube; in an artificial environment. in vi·tro adj. In an artificial environment outside a living organism. as well as influence the in vivo in vivo /in vi·vo/ (ve´vo) [L.] within the living body. in vi·vo adj. Within a living organism. in vivo adv. endocrine function of experimental animals and livestock that consume high quantities of these phytoestrogen-laden plants (Bennetts et al. 1946; Facemire et al. 1995; Whitten and Patisaul 2001; Zava et al. 1997). The mechanism of action is defined by vertebrate ERs, which bind phytoestrogen ligands, endogenous ligands, and endocrine-disrupting chemicals (EDCs) with specific affinity. Similarly, nodulation D protein (NodD) receptors in Rhizobium soil bacteria recognize phytoestrogens as recruitment signals to initiate nitrogen-fixing symbiosis. The specific affinity for and recognition of similar natural and synthetic ligands by receptors such as ER and NodD provide an example of shared or analogous functionality (Fox et al. 2001, 2004). In an evolutionary context, it may seem odd that phytochemical phy·to·chem·i·cal n. A nonnutritive bioactive plant substance, such as a flavonoid or carotenoid, considered to have a beneficial effect on human health. signals, produced by plants as recruiting signals for symbiotic soil bacteria, are intercepted by humans and affect estrogenic signaling by binding to ERs and influencing estrogen-responsive gene expression. Both plants and humans have the ability to synthesize steroids, and plants express proteins that are homologous in sequence and identical in function to human 5[alpha]-reductase enzymes, in that they both catalyze the reduction of steroid substrates (Li et al. 1997). Nevertheless, how is it that plants and humans, two organisms known to be derived from separate lineages (Meyerowitz 2002), both share the ability to produce and recognize steroid signals? After all, there are no ERs in plants or in their most common partners, insects. However, one intended target of phytoestrogen signaling, Rhizobium soil bacteria, does express ligand-dependent transcriptional activator proteins/receptors, called NodD proteins, which have been reported to share genetic homology with the human ER (Gyorgypal and Kondorosi 1991; Long 1989). In addition, some Nod proteins have been shown to share significant sequence homology with human steroid biochemical intermediates (Baker 1989, 1991). Recent genetic sequence analysis has shown no significant nucleotide level homology between rhizobial NodD and human ER genes. Nevertheless, these two evolutionarily distant receptors both recognize and respond to a shared group of chemical signals and ligands, including both agonists and antagonists. A lack of homology at the nucleotide level does not preclude the possibility that NodD and ER are receptors with analogous signaling functions. In fact, recent advances in X-ray crystallography have helped uncover many examples of proteins that share little or no nucleotide level homology and yet, when crystallized, have been shown to share significant homology in three-dimensional protein folding, domains, and structural characteristics (Benner et al. 2000; Lai et al. 2000; Rives Language Rive (plural : rives) is a French word meaning "bank" (of a river). Geography Rives is the name of several places: France Rives is the name of 2 communes in France:
Although they share no common evolutionary ancestor, NodD and ER recognize and respond to a similar profile of chemical signals found in the environment. Convergent evolution may explain the shared ligand recognition properties common to both ER and NodD proteins. Convergent evolution is demonstrated when two species that do not share a common ancestor exhibit similar traits that have arisen, through natural selection, as adaptations to similar ecologic and environmental conditions or signals (Thompson 1999). I contend that NodD and ER may have separately evolved, in lineages leading to Rhizobium bacteria and vertebrates, to adapt to the presence of natural estrogenic ligands, such as those produced by vertebrates, fungi, and plants (phytoestrogens). Recent evolutionary analysis has found that some invertebrates express an ER, and phylogenetic analysis of these sequences has demonstrated that the ER is the earliest ancestral receptor of the entire steroid receptor family (Thornton 2001; Thornton et al. 2003). Conversely, the endogenous natural ligand for ER, [E.sub.2], is the terminal product of the steroid biochemical pathway. Therefore, when compared on an evolutionary time scale, the ER may have arisen long before its endogenous ligand, [E.sub.2], was produced. In this absence of [E.sub.2], ancestral ERs may yet have functioned as receptors for exogenous/environmental signals. At the time of the evolutionary emergence of the ER, organisms such as insects, fungi, bacteria, and plants existed and may have been actively producing chemical signals that served, then as they do today, as potent ER ligands. These environmental signals may have included a wide variety of phytoestrogens, including those that signal through rhizobial NodD receptors to initiate symbiosis. In addition to having specific affinity for and being activated by many of the same ligands and phytoestrogens, vertebrate ER proteins and rhizobial NodD proteins can also be affected by many of the same environmental cues and ligands. ER and NodD both require chaperone chaperone /chap·er·one/ (shap´er-on) someone or something that accompanies and oversees another. molecular chaperone proteins, hsp70 and GroESL, respectively, for proper folding and full activation of transcription (Cheung and Smith 2000; Nair et al. 1996; Takayama and Reed 2001; Yeh et al. 2002). Specific ligand binding to ER and NodD results in either activation or inhibition of responsive gene transcription Gene transcription The process by which genetic information is copied from DNA to RNA, resulting in a specific protein formation. Mentioned in: Gene Therapy ; therefore, both receptors exhibit ligand-concentration-dependent activity. Moreover, ligand binding to ER and NodD results in both receptors binding to highly conserved consensus sequences of DNA DNA: see nucleic acid. DNA or deoxyribonucleic acid One of two types of nucleic acid (the other is RNA); a complex organic compound found in all living cells and many viruses. It is the chemical substance of genes. , the estrogen response element and the Nod box, respectively, in the promoter regions of responsive genes. ER- or NodD-induced transcription of responsive genes is responsible for growth and differentiation events (Fisher and Long 1993; Katzenellenbogen et al. 2000; McLachlan 2001; van Rhijn and Vanderleyden 1995). ER can also be activated in a ligand-independent manner via cross-talk with growth factor signaling pathways (Bjornstrom and Sjoberg 2002; Frigo et al. 2002; Klotz et al. 2002). For example, ER can be activated via mitogen-activated protein kinase Mitogen-activated protein (MAP) kinases (EC 2.7.11.24) are serine/threonine-specific protein kinases that respond to extracellular stimuli (mitogens) and regulate various cellular activities, such as gene expression, mitosis, differentiation, and cell survival/apoptosis. (MAPK MAPK Mitogen-Activated Protein Kinase MAPK Map Kinase ) phosphorylation cascade members (Weinstein-Oppenheimer et al. 2002; Weldon et al. 2002). Interestingly, a member of the MAPK eukaryotic eukaryotic /eu·kary·ot·ic/ (u?kar-e-ot´ik) pertaining to a eukaryon or to a eukaryote. eukaryotic pertaining to eukaryosis. eukaryotic cells see cell. signal transduction pathway, Raf (MAPK kinase) protein, has a homologous protein in plants that also functions in signal transduction of the plant hormone ethylene (Clark et al. 1998). ER's ability to signal in the absence of ligand and be influenced by multiple signal transduction pathways, as well as ER's promiscuous binding of an array of environmental compounds, has led to hypotheses that the original signaling function of ER may have been as a receiver and translator of many varied environmental signals and cues. On the basis of the functional similarities listed above and their shared affinity for similar chemical signals, I propose that the evolutionarily distinct ER and NodD receptors are functionally analogous in their response to and mediation of chemical signaling. Therefore, it follows that both of these signaling systems are vulnerable to disruption by EDCs present in their shared environment. Disruption of Chemical Communication by Natural and Synthetic EDCs Initial studies (Fox et al. 2001), as well as the expanded studies (Fox et al. 2004), have shown that signaling via both ER and NodD receptors is adversely affected by a similar profile of EDCs at environmentally relevant concentrations. The original hypothesis--that phytoestrogens and EDCs that disrupt [E.sub.2]-ER signaling in mammalian cells (Blair et al. 2000; Danzo 1997) will similarly disrupt symbiotic Phytoestrogen-NodD signaling--has led to testing of more than 80 natural and synthetic environmental compounds, at a wide range of concentrations, for agonist and antagonist effects on phytoestrogen-NodD signaling. Environmental compounds, including phytoestrogens, fungal chemicals, insecticides, herbicides, plasticizers plasticizers mostly triaryl phosphates, such as tricresyl, triphenyl phosphates, which are poisonous. See also triorthocresyl phosphate. , polyaromatic hydrocarbons (PAHs), and polychlorinated biphenyls polychlorinated biphenyls, (pol´ēklôr´  nā´tid bīfē´n (PCBs), were chosen
because of their ability to disrupt endocrine signaling in vertebrates,
humans, and exposed wildlife as reported in numerous scientific reports
over the past 60 years (Bennetts et al. 1946; Bitman et al. 1968;
Guillette 2000; Korach et al. 1979; McLachlan et al. 1984; Nelson 1974).
EDCs were tested for disruption of NodD signaling by measuring effects
of EDCs on phytoestrogen-induced NodD-responsive reporter gene
expression (Table 1).In the presence of 1 [micro]M luteolin inducer inducer /in·duc·er/ (in-dldbomacs´er) a molecule that causes a cell or organism to accelerate synthesis of an enzyme or sequence of enzymes in response to a developmental signal. in·duc·er n. , NodD activates the transcription of a number of nodulation (nod) genes. To measure antagonist effects of EDCs, I added increasing concentrations of each EDC EDC See: Export Development Corp. (insecticides, herbicides, plasticizers, PCBs, PAHs, synthetic and natural hormones, and phytochemicals) in the presence of 1 [micro]M luteolin and quantified the effects of EDCs on expression of a responsive nod gene fused to a lacZ reporter gene. The maximum inhibition ([I.sub.max]) of nod gene expression was quantified for each EDC tested (Table 1). The natural NodD ligand luteolin was set as 100% potency (++++). Each EDC tested was ranked in order of the percent inhibition of nod gene activation (relative percent potency): 1-25% (+), 25-50% (++), 50-75% (+++), 75 -00% (++++), and above 100% (+++++). Similarly, potency data were pooled from the literature for many of the EDCs tested in this study regarding potency with which each EDC caused disruption (either agonist or antagonist) of signaling through ER (Coldham et al. 1997; Collins-Burow et al. 2000; Kuiper et al. 1997; Petit et al. 1997; Sheeler et al. 2000; Zava et al. 1997). The natural ER ligand [E.sub.2] was set as 100% potency for ER signaling, and EDCs were ranked in order of most potent disruption of [E.sub.2]-ER signaling. Potency data for each EDC in the NodD and ER signaling systems are reported in Table 1 and Figure 1. [FIGURE 1 OMITTED] For comparative analysis of NodD-disruption data (Fox et al. 2001, 2003), I ranked the potency with which each EDC disrupted phytoestrogen-NodD signaling. This EDC "potency profile" was used to construct the x-axis of Figure 1. In order to create a comparable "potency profile" of EDCs that affect ER signaling, I pooled data from the existing body of scientific literature concerning the effects of phytoestrogens and EDCs on ER signaling (Coldham et al. 1997; Collins-Burow et al. 2000; Kuiper et al. 1997; Petit et al. 1997; Sheeler et al. 2000; Zava et al. 1997) and used these data to create the y-axis of Figure 1. This allowed me to compose a "potency profile" for each EDC, ranking the relative amount of disruption to both ER-mediated and NodD-mediated signaling. By graphing the potency data for all EDCs tested, ranking relative effects on either estrogenic (y-axis) or symbiotic (x-axis) signaling, I determined four different categories of EDCs (Figure 1). The largest category in number consists of EDCs that are not potent effectors of either ER or NodD signaling (quadrant 4), whereas the two smallest categories consist of EDCs that are potent signal disruptors of either only ER signaling (quadrant 1) or only NodD signaling (quadrant 3) (Figure 1). Finally, quadrant 2 contains EDCs that are potent disruptors of both ER and NodD signaling; this quadrant illustrates that ligand affinity and signaling properties are often shared in common between estrogenic and symbiotic signaling (Figure 1). The category of shared disruptors was primarily composed of phytoestrogens or plant-derived compounds such as stilbenes. Interestingly, all of the stilbenes and bisphenolic compounds tested fall into this shared disruptor category. The predominance of phytoestrogens as potent agents for ER and NodD signaling further supports the theory that an evolutionarily ancient or ancestral ER may have recognized and responded to phytoestrogens even before the emergence of the natural endogenous ligand [E.sub.2]. The few synthetic EDCs found to be potent disruptors of both ER and NodD signaling include the estrogenic plastics by-product and surfactant Surfactant Definition Surfactant is a complex naturally occurring substance made of six lipids (fats) and four proteins that is produced in the lungs. It can also be manufactured synthetically. bisphenol A and the pharmaceutical estrogen diethylstilbestrol diethylstilbestrol: see DES. (DES). Both bisphenol A and DES are among the earliest synthesized pharmaceutical estrogens (Dodds and Lawson 1936; Dodds et al. 1938). In fact, DES is a stilbestrol stil·bes·trol n. DES. stilbestrol a synthetic estrogen used in the treatment of female animals for infertility and bitches for urinary incontinence. derivative whose core structure is that of the plant product stilbene stil·bene n. A colorless or yellowish unsaturated crystalline hydrocarbon compound that is the chemical basis for diethylstilbestrol and other synthetic estrogenic compounds. , of which 4-OH-stilbene was also found to be an active disruptor of ER and NodD signaling. Other studies have indicated that this very same group of compounds--stilbenes, bisphenol A, and DES--are not only potent estrogens but also inhibitors of microtubule microtubule Tubular structure enclosed by a membrane found within animal and plant cells. Of varying length, they have several functions. They help give shape to many cells and are major components of cilia and flagella, participate in the formation of the spindle during polymerization polymerization Any process in which monomers combine chemically to produce a polymer. The monomer molecules—which in the polymer usually number from at least 100 to many thousands—may or may not all be the same. (Metzler and Pfeiffer 1995). Many of the phytochemicals found to be disruptors of ER and NodD signaling are themselves signaling molecules signaling molecules substances synthesized by cells for purposes of extracellular communication between cells. produced by soybeans and clover to signal to and recruit their own specific symbiotic strains of rhizobia Rhizobia (from the Greek words rhiza = root and bios = Life) are soil bacteria that fix nitrogen (diazotrophy) after becoming established inside root nodules of legumes (Fabaceae). The rhizobia cannot independently fix nitrogen, and require a plant host. and mycorrhiza mycorrhiza Product of close association between the branched, tubular filaments (hyphae) of a fungus and the roots of higher plants. The association usually enhances the nutrition of both the host plant and the fungal symbiont. . One may hypothesize hy·poth·e·size v. hy·poth·e·sized, hy·poth·e·siz·ing, hy·poth·e·siz·es v.tr. To assert as a hypothesis. v.intr. To form a hypothesis. that these related phytochemical-symbiont signaling webs may also be potential targets of disruption by EDCs found in the environment. I have identified fundamental similarities in the profile of EDCs that disrupt phytochemical-NodD symbiotic signaling and [E.sub.2]-ER hormone signaling, further supporting the theory of an evolutionary convergence of chemical communication pathways (Baker 1992b; Wynne-Edwards 2001). Therefore, it is probable that EDCs and other phenolic phe·no·lic adj. Of, relating to, containing, or derived from phenol. n. Any of various synthetic thermosetting resins, obtained by the reaction of phenols with simple aldehydes and used as adhesives. ring substitution compounds, which disrupt NodD symbiotic signal and ER signaling, may be capable of disrupting a much broader web of signaling than had previously been considered (Firmin et al. 1986; Djordjevic et al. 1987; Peters and Long 1988). I have used the same reasoning that has been applied to studying the effects of EDCs in vertebrates and have found parallels between the profile of EDCs and the effects on endogenous signaling in the plant-rhizobial system. In addition, the chemicals tested are commonly found in the soil environment in concentrations comparable with those used in other assays, and a lower level of nod gene expression may result in reduced symbiotic signaling. Although endocrine disruption studies in vertebrates have been criticized for exceeding the range of environmentally relevant concentrations of EDCs, there is no question that EDCs are abundantly used and found in the same environment as NodD-phytoestrogen signaling. Rhizobium are ubiquitous in the soil environment of agricultural regions in the first 10 in. below ground. EDCs, such as organochlorine or·gan·o·chlo·rine n. Any of various hydrocarbon pesticides, such as DDT, that contain chlorine. pesticides, are applied in amounts measured in tons to the very agricultural fields in which this new "target" of endocrine disruption exists. Significant residual levels of EDCs, such as DDT DDT or 2,2-bis(p-chlorophenyl)-1,1,1,-trichloroethane, chlorinated hydrocarbon compound used as an insecticide. First introduced during the 1940s, it killed insects that spread disease and feed on crops. , can be measured 20 years after spraying in micromolar or parts-per-billion concentrations (Aigner et al. 1998; Mitra and Raghu 1998). Therefore, depending on the timing of pesticide application, it is probable that phytochemicals produced by host plants are competing with micromolar or millimolar concentrations of active endocrine disruptors for signaling to NodD receptors in soil bacteria. Recent studies of crops that rely on nitrogen-fixing symbiosis in agricultural areas with heavy pesticide use have reported stunted plant growth and reduced mycorrhiza and rhizobia symbiosis (Abd-Alla et al. 2000), mirroring the effects predicted by in vitro laboratory studies (Fox et al. 2001, 2004). These data identify a novel target of EDCs, the chemical communication between two organisms, which mediates symbiosis. Furthermore, in vitro laboratory results showing EDC inhibition of the symbiotic signaling system necessary for recruitment of nitrogen-fixing bacteria to plants for symbiosis (Fox et al. 2001, 2004) may indicate the mechanism behind deleterious effects reported in the field. Implications Phenotypic evidence of endocrine disruption commonly observed when vertebrates are exposed to high concentrations of organochlorine pesticides and pollutants include feminization feminization /fem·i·ni·za·tion/ (fem?i-ni-za´shun) 1. the normal development of primary and secondary sex characters in females. 2. the induction or development of female secondary sex characters in the male. of fish, reduced phallus phallus /phal·lus/ (fal´us) pl. phal´li 1. penis. 2. a representation of the penis. 3. the primordium of the penis or clitoris that develops from the genital tubercle. size of reptiles, decreased mating ability in mammals, reduced fertility and viability in a variety of species, and disruption of [E.sub.2] signaling to ERs (Bennetts et al. 1946; Danzo 1997; Facemire et al. 1995; McLachlan 2001; Tyler et al. 1998). ER homologues have been found in species as evolutionarily distant as invertebrates and humans (Thornton 2001; Thornton et al. 2003). In addition, many homologues of human signaling pathway members (Bolduc et al. 2003; Stracke et al. 2002), including estrogen-like receptors, have been identified in plants (Milanesi et al. 2001) and, as discussed here, may have analogous receptors in Rhizobium bacteria. Meanwhile, most research on endocrine disruption has focused on what effects EDCs and phytoestrogens have on hormone signaling in humans and wildlife, but the evolutionary targets of phytoestrogen signaling, namely, symbiotic soil bacteria, had been overlooked as a target of EDCs. Communication via hormone signaling is subject to cross-talk and disruption by both natural and synthetic environmental chemical signals, which are communicated to all organisms residing in a shared ecosystem. Phytoestrogen signaling is a prime example of signal cross-talk found in the environment. Phytoestrogens, produced as recruitment signals for symbiotic soil bacteria, are recognized as hormone signals by some herbivores resulting in reduced fecundity fecundity /fe·cun·di·ty/ (fe-kun´dit-e) 1. in demography, the physiological ability to reproduce, as opposed to fertility. 2. ability to produce offspring rapidly and in large numbers. (Wynne-Edwards 2001). In addition, these same phytoestrogens may be responsible for hormone alterations in humans that lead to reduced risk of hormone-dependent cancers (Zava and Duwe 1997). This example illustrates how a hormone signal, released into the environment for the sole purpose of communicating with a receptor in a target organism, may have unintentional consequences as a hormone signal that communicates to any and all nontarget organisms with analogous signal receptors. In most studies involving environmental estrogens, the receptor of endocrine-disrupting signals has been identified as the ER. The limitation to operating under the assumption that EDCs are only a threat to organisms that express a recognizable ER is that many invertebrates have been overlooked as targets of endocrine disruption. Only recently have laboratories begun looking for Looking for In the context of general equities, this describing a buy interest in which a dealer is asked to offer stock, often involving a capital commitment. Antithesis of in touch with. endocrine disruption phenotypes in organisms such as coral, Daphnia, and Caenorhabditis elegans, which do not have classic ERs (Custodia et al. 2001; Tarrant et al. 1999; Wu et al. 2001). Additionally, by focusing on extreme endocrine disruption phenotypes, such as sex reversal sex reversal n. A process that changes the sexual identity of an individual from one sex to the other, often through a combination of surgical, pharmacologic, and psychiatric procedures. in fish or amphibians amphibians members of the animal class Amphibia. Includes frogs, toads, newts, salamanders and cecilians all capable of living on land or in water. (Hayes et at. 2002; Jobling et al. 2002), more subtle but important phenotypes of endocrine disruption may be overlooked. After all, EDC-inhibition of one member of a signaling or regulatory cascade (NodD in rhizobia) results in reduced symbiotic gene activation leading to population-level effects on nitrogen-fixing symbiosis (Fox et al. 2004). On the basis of these emerging examples of endocrine disruption in a variety of unexpected target species, I propose a more mechanism-based approach for assessing the effects of EDCs on ecosystem-wide signaling webs. By studying the intraorganismal and interorganismal communication mediated by hormone signaling in a multitude of species, we can begin to identify analogous signaling systems based on how EDCs and environmental estrogens may disrupt these signaling webs. An example of a signaling web, or a microcosm of hormone signals mediating communication, may be found in 1 [in..sup.2] of soil, where signals are produced by plants to communicate with other plants, to recruit symbiotic soil bacteria and fungi, and to ward off nematodes and aphid pests (Dunn and Handelsman 2002; Guerrieri et al. 2002; Stracke et al. 2002). Just as soil bacteria must receive and integrate each of these hormone signals in the soil microenvironment microenvironment /mi·cro·en·vi·ron·ment/ (-en-vi´ron-ment) the environment at the microscopic or cellular level. and find the one recruitment phytochemical signal among so much chemical signaling "noise," so must humans exist in an environment awash in hormone chemical signals and yet still recognize appropriate endogenous hormone signals. As if this task of signal communication and interpretation were not daunting daunt tr.v. daunt·ed, daunt·ing, daunts To abate the courage of; discourage. See Synonyms at dismay. [Middle English daunten, from Old French danter, from Latin enough, each organism must contend not only with natural hormone signals but also with an ever-increasing number of "unintentional" hormonally active synthetic chemicals in the environment (Seiler 2002). By identifying and monitoring analogous signaling systems, we could more easily understand how the release of an abundance of synthetic chemicals into the environment, such as organochlorine pesticides intended to antagonize insects and unwanted pests, could inadvertently disrupt hormone signaling in a wide variety of organisms from mammals to symbiotic bacteria, all of whom rely on signaling webs for communication. After all, an assault on one form of signaling-based communication is likely an assault on many. As we begin to better understand the mechanisms by which organisms signal or communicate information, both endogenously and within their environment, we may discover an unlimited number of new targets for EDCs and environmental estrogens. Because signaling communication webs are not unidirectional, we must consider not only how synthetic chemicals produced by humans may adversely affect biota biota /bi·o·ta/ (bi-o´tah) all the living organisms of a particular area; the combined flora and fauna of a region. bi·o·ta n. The flora and fauna of a region. in the environment but also how signals originating in bacteria or plants may affect signaling within the human body (McFall-Ngai 2002). Studies of analogous signaling methods used by a number of organisms may shed light on endocrine signaling and human health. For instance, researchers have shown that genes necessary for mammalian pathogenic bacteria Pathogenic bacteria Bacteria that produce illness. Mentioned in: Gastroenteritis to establish chronic infections in humans are homologous to genes in Rhizobium responsible for infecting plant hosts and establishing symbiosis (LeVier et al. 2000). As more evidence of homologous and analogous hormone signals and receptors emerges, we must consider how the inadvertent hormone signaling of EDCs, which is known to disrupt signaling cascades, gene activation, and hormonal homeostasis homeostasis Any self-regulating process by which a biological or mechanical system maintains stability while adjusting to changing conditions. Systems in dynamic equilibrium reach a balance in which internal change continuously compensates for external change in a feedback , may not only affect individuals (fecundity, reproduction) but also confound ecosystem-wide communication webs leading to unpredictable population-level effects. The evolution of communication via hormone signaling may be one of the oldest and most crucial links shared between all organisms. To determine what is most important for the viability of an organism or an ecosystem, we must determine either what has been conserved over evolutionary time or what has been reinvented and selected for by convergent evolution (Baker 1992a, 2002; McLachlan 2001; Whiting et al. 2003). Communication via chemical signaling is a shared characteristic of all organisms and, thus, affects all members of an ecosystem. Therefore, I propose that chemical communication is a crucial component of ecosystem health and the primary target of EDCs found in the environment. The characterization of the disruption of an evolutionarily ancient symbiotic signaling system by EDCs (Fox et al. 2004) may provide insights into the mechanisms by which these same EDCs disrupt endocrine signaling in vertebrates. The study of analogous communication systems, such as mammalian endocrine signaling and plant-Rhizobium symbiotic signaling, will yield new insights into hormone signaling and disruption of hormone signaling by environmental estrogens and EDCs and may provide information on the evolution of nuclear receptors.
Table 1. EDCs disrupt NodD signaling and ER signaling.
Relative effect on
signaling
Percent
inhibition
of nod
expression ER- ER-
Chemicals tested ([I.sub.max]) NodD [alpha] [beta]
Insecticides
Pentachlorophenol 90 ++++ +
Methyl parathion 89 ++++
Kepone 42 ++
p,p'-DDT 45 ++ + +
p,p'-DDE 44 ++ ++
o,p'-DDT 43 ++ ++ +
o,p'-DDE 42 ++ +
p,p'-DDD 35 ++
o,p'-DDD 34 ++
Hexachlorocyclohexane 24 +
Dicofol 22 +
Malathion 20 +
Lindane 13 + ++
Toxaphene 7 +
Methoprene 5 +
Endosulfan None -
Endosulfan sulfate None - + +
Methoxychlor None - + +
Aldrin None -
Dieldrin None - +
Carbofuran None - +
EPTC None - +
Diazinon None -
Dursban None -
Herbicides
2,4,5-T 37 ++
2,4-D 32 ++ +
Pendimethalin 16 +
Trifluralin 12 + +
Atrazine 10 +
Metolachlor 10 +
Alachlor None - +
trans-Nonachlor None -
Acetochlor None -
Fungicide
Vinclozolin None -
Plasticizers
Bisphenol A 66 +++ +++ ++
tert-Octylphenol 25 ++ +++ +++
4-Nonylphenol 20 + +++ ++
Benzyl butylphthatlate 19 + +
PCBs
4-OH-2',3',4',5'-PCB 60 +++
4-OH-2',4',6'-PCB 56 +++
Arochlor 27 ++
3,3',4,5-PCB 23 +
2,3,4,5-PCB 15 +
2,4,6-PCB None -
PAHs
6-OH-chrysene 29 ++
cis-Nonachlor 12 +
Hormone-active compounds
DES 55 +++ +++++ +++
4-OH-stilbene 53 +++ +++
Zearalenone (fungal) 33 ++ ++++ ++
Progesterone 17 + +
ICI 182,780 15 + + +
Testosterone 10 + -
Estriol 7 + ++++
[E.sub.2] None - ++++ ++++
Phytochemicals
Genistein 86 ++++ ++++ +++++
Chrysin 85 ++++ +++ +
Coumestrol 76 ++++ ++++ ++++
Chalcone 60 +++
Kaempferol 59 +++ +++ +++
Daidzein None - +
Apigenin None - +++ ++
Luteolin None ++++ +
Abbreviations: -, no significant effect; 2,4-D,
2,4-dichlorophenoxyacetic acid; 2,4,5-T, 2,4,5-trichlorophenoxyacetic
acid; DDD, dichlorodiphenyldichloroethane; DDE,
dichlorodiphenyldichloroethylene; DDT,
dichlorodiphenyltrichloroethane; EPTC, S-ethyl dipropylthiocarbamate;
[I.sub.max], maximum inhibition. Luteolin was set as 100% potency
(++++) for NodD signaling. EDCs were ranked in order of the most
potent disruptor of nod gene activation (relative percent potency):
1-25% (+), 25-50% (++), 50-75% (+++), 75-100% (++++), and > 100%
(+++++). [E.sub.2] was set as the measure of 100% potency for ER
signaling, and EDCs were ranked in order of most potent disruption of
[E.sub.2]-ER signaling. Potency data for each EDC in the NodD and ER
signaling systems are also reported in Figure 1. Adapted from Fox
et al. (2004).
REFERENCES Abd-Alla MH, Omar SA, Karanxha S. 2000. The impact of pesticides on arbuscular mycorrhizal and nitrogen-fixing symbiosis in legumes Legumes A family of plants that bear edible seeds in pods, including beans and peas. Mentioned in: Cholesterol, High legumes (l . Appl Soil Ecol 14:191-200. Aigner EJ, Leone AD, Falconer RL. 1998. Concentrations and enantiomeric ratios of organochlorine pesticides in soils from the U.S. corn belt. Environ Science Technol 32:1162-1168. Baker ME. 1989. Human placental 17beta-hydroxysteroid dehydrogenase dehydrogenase /de·hy·dro·gen·ase/ (de-hi´dro-jen-as?) an enzyme that catalyzes the transfer of hydrogen or electrons from a donor, oxidizing it, to an acceptor, reducing it. de·hy·dro·gen·ase n. is homologous to NodG protein of Rhizobium meliloti. Mol Endocrinol 3:881-884. Baker ME. 1991. Genealogy of regulation of human sex and adrenal adrenal /ad·re·nal/ (ah-dre´n'l) 1. paranephric. 2. adrenal gland. 3. pertaining to an adrenal gland. ad·re·nal adj. 1. function, prostaglandin action, snapdragon snapdragon: see figwort. and petunia petunia, any plant of the genus Petunia, South American herbs of the family Solanaceae (nightshade family). The common garden petunias, planted also in window boxes, are all considered hybrids of white-flowered and violet-flowered species from Argentina. flower colors, antibiotics, and nitrogen fixation: functional diversity from two ancestral dehydrogenases. Steroids 56:354-360. Baker ME. 1992a. Evolution of regulation of steroid-mediated intercellular intercellular /in·ter·cel·lu·lar/ (-sel´u-lar) between or among cells. in·ter·cel·lu·lar adj. Located among or between cells. communication in vertebrates: insights from flavonoids flavonoids, n.pl common plant pigment compounds that act as antioxidants, enhance the effects of vitamin C, and strengthen connective tissue around capillaries. , signals that mediate plant-rhizobia symbiosis. J Steroid Biochem Mol Biol 41:301-308. Baker ME. 19925. Similarities between legume-rhizobium communication and steroid-mediated intercellular communication in vertebrates. Can J Microbiol 38:541-547. Baker ME. 1998. Flavonoids as Hormones: A Perspective from an Analysis of Molecular Fossils. New York:Plenum Press. Baker ME. 2002. Recent insights into the origins of adrenal and sex steroid receptors. J Mol Endocrinol 28:149-152. Benner SA, Chamberlin SG, Liberles DA, Govindarajan S, Knecht L. 2000. Functional inferences from reconstructed evolutionary biology involving rectified databases--an evolutionarily grounded approach to functional genomics. Res Microbiol 151:97-106. Bennetts HW, Underwood EJ, Shier shi·er adj. A comparative of shy1. FLA FLA Florida (old style) FLA Macromedia Flash (file extension) FLA Flash Files (file extension) FLA Fair Labor Association FLA Front Line Assembly . 1946. Breeding problem in sheep in the south-west division of West Australia. J Agric West Austral aus·tral adj. Of, relating to, or coming from the south. [Latin austr  lis, from auster, austr-, south. 23:1-12.Bitman J, Cecil HC, Harris SJ, Fries GF. 1968. Estrogenic activity of o,p-'DDT in the mammalian uterus and avian oviduct oviduct: see fallopian tube. . Science 162:371-372. Bjornstrom L, Sjoberg M. 2002, Signal transducers and activators of transcription as downstream targets of nongenomic estrogen receptor actions. Mol Endocrinol 16:2202-2214. Blair RM, Fang H, Branham WS, Hass BS, Dial SL, Moland CL, et al. 2000. The estrogen receptor relative binding affinities of 188 natural and xenochemicals: structural diversity of ligands. Toxicol Sci 54:138-153. Bolduc N, Ouellet M, Pitre F, Brisson LF. 2003, Molecular characterization of two plant BI-1 homologues which suppress Bax-induced apoptosis in human 293 cells. Planta 216:377-386. Cheek AO, Vonier PM, Oberdorster E, Colins-Burow B, McLachlan JA. 1998. Environmental signaling: a biological context for endocrine disruption. Environ Health Perspect 106(suppl 1):5-10. Cheung J, Smith DF. 2000, Molecular chaperone interactions with steroid receptors: an update. Mol Endocrinol 14:939-946. Clark KL, Larsen PB, Wang X, Chang C, 1998. Association of the Arabidopsis CTR See click-through rate. 1 Raf-like kinase with the ETR ETR Estimated Time of Return/Repair ETR Early to Rise (health e-zine) ETR Effective Tax Rate Etr Etruscan (linguistics) ETR Eastern Test Range ETR Express Toll Route 1 and ERS ethylene receptors. Proc Natl Acad Sci USA 95:5401-5406. Coldham NG, Dave M, Sivapathasundaram S, McDonnell DP, Connor C, Sauer MJ. 1997. Evaluation of a recombinant yeast cell estrogen screening assay. Environ Health Perspect 105:734-742. Collins-Burow BM, Burow ME, Duong BN, McLachlan JA. 2000. Estrogenic and antiestrogenic activities of flavonoid phytochemicals through estrogen receptor binding-dependent and -independent mechanisms. Nutr Cancer 38:229-244. Crump D, Werry K, Veldhoen N, Van Aggelen G, Helbing CC. 2002. Exposure to the herbicide acetochlor alters thyroid hormone-dependent gene expression and metamorphosis in Xenopus laevis. Environ Health Perspect 110:1199-1205. Custodia N, Won SJ, Novillo A, Wieland M, Li C, Callard IP. 2001. Caenorhabditis elegans as an environmental monitor using DNA microarray analysis. Ann NY Acad Sci 948:32-42. Danzo BJ. 1997. Environmental xenobiotics may disrupt normal endocrine function by interfering with the binding of physiological ligands to steroid receptors and binding proteins. Environ Health Perspect 105:294-301. Djordjevic MA, Redmond JW, Batley M, Rolfe BG. 1987. Clovers secrete specific phenolic compounds which either stimulate or repress re·press v. 1. To hold back by an act of volition. 2. To exclude something from the conscious mind. nod gene expression in Rhizobium trifoli. EMBO J 6:1173-1179. Dodds EC, Goldberg L, Lawson W, Robinson R. 1938. Oestrogenic oestrogenic (ōˈ·es·tr activity of certain synthetic compounds. Nature 141:247-249. Dodds EC, Lawson W. 1936. Synthetic oestrogenic agents without the phenanthrene phenanthrene /phe·nan·threne/ (fe-nan´thren) a tricyclic aromatic hydrocarbon occurring in coal tar; toxic and carcinogenic. phe·nan·threne n. nucleus. Nature 137:996. Dunn AK, Handelsman J. 2002. Toward an understanding of microbial microbial pertaining to or emanating from a microbe. microbial digestion the breakdown of organic material, especially feedstuffs, by microbial organisms. communities through analysis of communication networks. Antonio Van Leeuwenhoek 81:565-574. Facemire CF, Gross TS, Guilette LJ. 1995. Reproductive impairment in the Florida panther: nature or nurture. Environ Health Perspect 103(suppl 4):79-86. Firmin JL, Wilson KE, Rossen L, Johnston AWB See House Air Waybill. . 1986. Flavonoid activation of nodulation genes in Rhizobium reversed by other compounds present in plants. Nature 324:90-93. Fisher RF, Long SR. 1993. Interactions of NodD at the nod box: NodD binds to two distinct sites on the same face of the helix and induces a bend in the DNA. J Mol Biol 233:336-348. Fox JE, Starcevic M, Jones PE, Burow ME, McLachlan JA. 2004. Phytoestrogen signaling and symbiotic gene activation are disrupted by endocrine-disrupting chemicals. Environ Health Perspect 112:672-677. Fox JE, Starcevic M, Kow KY, Burow ME, McLachlan JA. 2001. Nitrogen fixation. Endocrine disrupters and flavonoid signalling. Nature 413:128-129. Frigo DE, Duong BN, Melnik LI, Schief LS, Collins-Burow BM, Pace DK, et al. 2002. Flavonoid phytochemicals regulate activator Protein-1 signal transduction pathways in endometrial endometrial /en·do·me·tri·al/ (en?do-me´tre-il) pertaining to the endometrium. endometrial, n relating to the end-ometrium or cavity of the uterus. and kidney stable cell lines. J Nutr 132:1848-1853. Guerrieri E, Poppy GM, Powell W, Rao R, Pennacchio F. 2002. Plant-to-plant communication mediating in-flight orientation of Aphidius ervi. J Chem Ecol 28:1703-1715. Guillette LJ Jr. 2000. Organochlorine pesticides as endocrine disruptors in wildlife. Cent Eur J Public Health 8(suppl):34-35. Gyorgypal Z, Kondorosi A. 1991. Homology of the ligand-binding regions of Rhizobium symbiotic regulatory protein NodD and vertebrate nuclear receptors. Mol Gen Genet genet: see civet. 226:337-340. Hayes TB, Collins A, Lee M, Mendoza M, Noriega N, Stuart AA, et al. 2002. Hermaphroditic her·maph·ro·dite n. 1. An animal or plant exhibiting hermaphroditism. 2. Something that is a combination of disparate or contradictory elements. , demasculinized frogs after exposure to the herbicide atrazine atrazine a triazine herbicide; it is not poisonous at levels of intake likely to be encountered in agriculture. atrazine Toxicology A nonphytoestrogenic herbicide. See Phytoestrogen. at low ecologically relevant doses. Proc Natl Acad Sci USA 99:5476-5480. Ishihara A, Nishiyama N, Sugiyama S, Yamauchi K. 2003. The effect of endocrine disrupting chemicals on thyroid hormone binding to Japanese quail transthyretin and thyroid hormone receptor The thyroid hormone receptor[1] is a type of nuclear receptor that is activated by binding thyroid hormone.[2] Among its most important functions are regulation of metabolism and heart rate. . Gen Comp Endocrinol 134:36-43. Jobling S, Beresford N, Nolan M, Rodgers-Gray T, Brighty GC, Sumpter JP, et al. 2002. Altered sexual maturation and gamete gamete (găm`ēt): see reproduction. production in wild roach (Rutilus rutilus) living in rivers that receive treated sewage effluents. Biol Reprod 66:272-81. Katzenellenbogen BS, Choi I, Delage-Mourroux R, Ediger TR, Martini PG, Montano M, et al. 2000. Molecular mechanisms of estrogen action: selective ligands and receptor pharmacology. J Steroid Biochem Mol Biol 74:279-285. Kay RR. 1998. The biosynthesis Biosynthesis The synthesis of more complex molecules from simpler ones in cells by a series of reactions mediated by enzymes. The overall economy and survival of the cell is governed by the interplay between the energy gained from the breakdown of compounds of differentiation-inducing factor, a chlorinated signal molecule regulating Dictyostelium development. J Biol Chem 273:2669-2675. Klotz DM, Hewitt SC, Ciana P, Raviscioni M, Lindzey JK, Foley J, et al, 2002. Requirement of estrogen receptor-[alpha] in insulin-like growth factor-1 (IGF-1)-induced uterine responses and in vivo evidence for IGF-1/estrogen receptor cross-talk. J Biol Chem 277:8531-8537. Koonin EV, Wolf YI, Karev GP. 2002. The structure of the protein universe and genome evolution. Nature 420:218-223. Korach K0S, Metzler M, McLachlan JA. 1979. Diethylstilbestrol metabolites Metabolites Substances produced by metabolism or by a metabolic process. Mentioned in: Interactions and analogs. New probes for the study of hormone action. J Biol Chem 254:8963-8968. Kuiper GJM GJM Golden Jubilee Medal GJM Gay Japanese Male , Lemmen JG, Carlsson B, Corton JC, Safe SH, van der Saag PT, et al. 1997, Interaction of estrogenic chemicals and phytoestrogens with estrogen receptor [beta]. Endocrinology 139:4252-4263. Lai CH, Chou CY, Ch'ang LY, Liu CS, Lin W. 2000. Identification of novel human genes evolutionarily conserved in Caenorhabditis elegans by comparative proteomics. Genome Res 10:703-713. LeVier K, Phillips RW, Grippe grippe: see influenza. VK, Roop RM II, Walker GC. 2000. Similar requirements of a plant symbiont symbiont /sym·bi·ont/ (sim´bi-ont) (sim´be-ont) an organism living in a state of symbiosis. symbiont an organism or species living in a state of symbiosis. and a mammalian pathogen for prolonged intracellular survival. Science 287:2492-2493. Li J, Biswas MG, Chao A, Russell DW, Chory J. 1997. Conservation of function between mammalian and plant steroid 5[alpha]-reductases. Proc Natl Acad Sci USA 94:3554-3559. Long SR. 1989. Rhizobium-legume nodulation: life together in the underground. Cell 56:203-214. McFall-Ngai MJ. 2002. Unseen forces: the influence of bacteria on animal development. Dev Biol 242:1-14. McLachlan JA. 2001. Environmental signaling: what embryos and evolution teach us about endocrine disrupting chemicals. Endocr Rev 22:319-341. McLachlan JA, Korach KS, Newbold RR, Degen GH. 1984. Diethylstilbestrol and other estrogens in the environment. Fundam Appl Toxicol 4:686-691. Metzler M, Pfeiffer E. 1995. Effects of estrogens on microtubule polymerization in vitro: correlation with estrogenicity. Environ Health Perspect 103(suppl 7):21-22. Meyerowitz EM. 2002. Plants compared to animals: the broadest comparative study of development. Science 295:1482-1485. Milanesi L, Monje P, Boland R. 2001. Presence of estrogens and estrogen receptor-like proteins in Solanum Solanum a widespread plant genus of the family Solanaceae which contains a number of valuable crop plants but also some poisonous ones. Poisoning may be due to (1) the presence in the plant of toxic glycoalkaloids which cause diarrhea, (2) alkamines, e.g. glaucophyllum. Biochem Biophys Res Commun 289:1175-1179. Mitra J, Raghu K. 1998. Long term DDT pollution in tropical soils: effect of DDT and degradation products on soil microbial activities leading to soil fertility. Bull Environ Contam Toxicol 60:585-591. Moriyama K, Tagami T, Akamizu T, Usui T, Saijo M, Kanamoto N, et al. 2002. Thyroid hormone action is disrupted by bisphenol A as an antagonist. J Clin Endocrinol Metab 87:5185-5190. Nair SC, Toran EJ, Rimerman RA, Hjermstad S, Smithgall TE, Smith DF. 1996. A pathway of multi-chaperone interactions common to diverse regulatory proteins: estrogen receptor, Fes tyrosine kinase, heat shock transcription factor Hsf1, and the aryl hydrocarbon receptor The Aryl hydrocarbon receptor (AhR) is member of the family of basic-helix-loop-helix transcription factors. AhR is a cytosolic transcription factor that is normally inactive, bound to several co-chaperones. . Cell Stress Chaperones 1:237-250. Nelson JA. 1974. Effects of dichlorodiphenyltrichloroethane di·chlo·ro·di·phen·yl·tri·chlo·ro·eth·ane n. DDT. (DDT) analogs and polychlorinated biphenyl (PCB PCB: see polychlorinated biphenyl. PCB in full polychlorinated biphenyl Any of a class of highly stable organic compounds prepared by the reaction of chlorine with biphenyl, a two-ring compound. ) mixtures on 17[beta]-[[sup.3]H]estradiol binding to rat uterine receptor. Biochem Pharmacol 23:447-451. Oberdorster E, Clay MA, Cottam DM, Wilmot FA, McLachlan JA, Milner MJ. 2001, Common phytochemicals are ecdysteroid agonists and antagonists: a possible evolutionary link between vertebrate and invertebrate invertebrate (ĭn'vûr`təbrət, –brāt'), any animal lacking a backbone. The invertebrates include the tunicates and lancelets of phylum Chordata, as well as all animal phyla other than Chordata. steroid hormones. J Steroid Biochem Mol Biol 77:229-238. Peters NK, Frost JW, Long SR. 1986. A plant flavone fla·vone n. A crystalline compound, C15H10O2, the parent substance of a number of important yellow pigments, occurring on the leaves or in the stems and seed capsules of many primroses. Noun 1. , luteolin, induces expression of Rhizobium meliloti nodulation genes. Science 233:977-980. Peters NK, Long SR. 1988, Alfalfa root exudates and compounds which promote or inhibit induction of Rhizobium meliloti nodulation genes. Plant Physiol 88:396-400. Petit F, Le Goff P, Cravedi JP, Valotaire Y, Pakdel F. 1997. Two complementary bioassays for screening the estrogenic potency of xenobiotics: recombinant yeast for trout estrogen receptor and trout hepatocyte hepatocyte /hep·a·to·cyte/ (hep´ah-to-sit?) a hepatic cell. hep·a·to·cyte n. A parenchymal liver cell. Hepatocyte A liver cell. cultures. J Mol Endocrinol 19:321-335. Rives AW, Galitski T. 2003. Modular organization of cellular networks. Proc Natl Acad Sci USA 100:1128-1133. Seiler JP. 2002. Pharmacodynamic activity of drugs and ecotoxicology--can the two be connected? Toxicol Lett 131:105-115. Sheeler CQ, Dudley MW, Khan SA. 2000. Environmental estrogens induce transcriptionally active estrogen receptor dimers in yeast: activity potentiated by the coactivator RIP140. Environ Health Perspect 108:97-103. Stracke S, Kistner C, Yoshida S, Mulder L, Sato S, Kaneko T, et al. 2002. A plant receptor-like kinase required for both bacterial and fungal symbiosis, Nature 417:959-962. Suel GM, Lockless SW, Wall MA, Ranganathan R. 2003. Evolutionarily conserved networks of residues mediate allosteric allosteric /al·lo·ster·ic/ (al?o-ster´ik) pertaining to allostery. allosteric pertaining to an effect on the biological function of a protein, produced by a compound not directly involved in that function (an allosteric communication in proteins. Nat Struct Biol 10:59-69. Takayama S, Reed JC. 2001. Molecular chaperone targeting and regulation by BAG family proteins. Nat Cell Biol 3:E237-241. Takeshita A, Koibuchi N, Oka J, Taguchi M, Shishiba Y, Ozawa Y. 2001. Bisphenol-A, an environmental estrogen, activates the human orphan nuclear receptor, steroid and xenobiotic xen·o·bi·ot·ic adj. Foreign to the body or to living organisms. Used of chemical compounds. n. A xenobiotic chemical. xenobiotic any substance, harmful or not, that is foreign to the animal's biological system. receptor-mediated transcription. Eur J Endocrinol 145:513-517. Tarrant AM, Atkinson S, Atkinson MJ. 1999. Estrone estrone /es·trone/ (es´tron) an estrogen isolated from pregnancy urine, human placenta, palm kernel oil, and other sources, also prepared synthetically; for properties and uses, see estrogen. and estradiol-17[beta] concentration in tissue of the scleractinian coral, Montipora verrucosa. Comp Biochem Physiol A Mol Integr Physiol 122:85-92. Thompson JN. 1999. The evolution of species interactions. Science 284:2116-2118. Thornton JW. 2001. Evolution of vertebrate steroid receptors from an ancestral estrogen receptor by ligand exploitation and serial genome expansions. Proc Natl Acad Sci USA 98:5671-5676. Thornton JW, Need E, Crews D. 2003. Resurrecting the ancestral steroid receptor: ancient origin of estrogen signaling. Science 301:1714-1717. Todd AE, Orengo CA, Thornton JM. 2001. Evolution of function in protein superfamilies, from a structural perspective. J Mol Biol 307:1113-1143. Town CD, Gross JD, Kay RR. 1976. Cell differentiation without morphogenesis morphogenesis /mor·pho·gen·e·sis/ (mor?fo-jen´e-sis) the evolution and development of form, as the development of the shape of a particular organ or part of the body, or the development undergone by individuals who attain the type to in Dictyostelium discoideum. Nature 262:717-719. Tyler CR, Jobling S, Sumpter JP. 1998. Endocrine disruption in wildlife: a critical review of the evidence. Crit Rev Toxicol 28:319-361. van Rhijn P, Vanderleyden J. 1995. The Rhizobium-plant symbiosis. Microbiol Rev 59:124-142. Weinstein-Oppenheimer CR, Burrows C, Steelman LS, McCubrey JA. 2002. The effects of beta-estradiol on Raf activity, cell cycle progression and growth factor synthesis in the MCF-7 breast cancer cell line. Cancer Biol Ther 1:256-262. Weldon CB, Scandurro AB, Rolfe KW, Clayton JL, Elliott S, Butler NN, et al. 2002, Identification of mitogen-activated protein kinase kinase Mitogen-activated protein kinase kinase (sic) is a kinase enzyme which phosphorylates mitogen-activated protein kinase. It is also known as MAP2K. It is classified as EC 2.7.12.2. as a chemoresistant pathway in MCF-7 cells by using gene expression microarray. Surgery 132:293-301. Whiting MF, Bradler S, Maxwell T. 2003. Loss and recovery of wings in stick insects. Nature 421:264-267. Whitten PL, Patisaul HB. 2001. Cross-species and interassay comparisons of pbytoestrogen action. Environ Health Perspect 109(suppl 1):5-20. Wu WZ, Li W, Xu Y, Wang JW. 2001. Long-term toxic impact of 2,3,7,8-tetrachlorodibenzo-p-dioxin on the reproduction, sexual differentiation, and development of different life stages of Gobiocypris rarus and Daphnia magna. Ecotoxicol Environ Saf 48:293-300. Wynne-Edwards KE. 2001. Evolutionary biology of plant defenses against herbivory and their predictive implications for endocrine disruptor susceptibility in vertebrates, Environ Health Perspect 109:443-448. Yeh KC, Peck MC, Long SR. 2002. Luteolin and GroESL modulate in vitro activity of NodD. J Bacteriol 184:525-530. Zava DT, Blen M, Duwe G. 1997. Estrogenic activity of natural and synthetic estrogens in human breast cancer cells in culture. Environ Health Perspect 105(suppl 3):637-645. Zava DT, Duwe G. 1997, Estrogenic and antiproliferative properties of flavonoids in human breast cancer cells in vivo. Nutr Cancer 27:31-40. Jennifer E. Fox (1,2) (1) Environmental Endocrinology Laboratory, Center for Bioenvironmental bi·o·en·vi·ron·men·tal adj. Having to do with the relationship between the environment and living organisms: Bioenvironmental engineers are studying the effects of toxic chemicals on life in the area. Research at Tulane and Xavier Universities, New Orleans, Louisiana, USA; (2) Center for Ecology and Evolutionary Biology Some U.S. universities are home to degree programs entitled Ecology and Evolutionary Biology, offering integrated studies in the disciplines of ecology and evolutionary biology. and Department of Biology, University of Oregon The University of Oregon is a public university located in Eugene, Oregon. The university was founded in 1876, graduating its first class two years later. The University of Oregon is one of 60 members of the Association of American Universities. , Eugene, Oregon, USA Address correspondence to J.E. Fox, University of Oregon, 335 Pacific Hall, Eugene, OR 97403 USA. Telephone: (541) 346-1537. Fax (541) 346-2364. E-mail: jenfox@uoregon.edu J.E.F. was supported by a National Science Foundation graduate fellowship. All work was supported by U.S. Department of Energy grant 540841. The author declares she has no competing financial interests. Received 14 May 2003; accepted 27 January 2004. |
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