Certain Styrene Oligomers Have Proliferative Activity on MCF-7 Human Breast Tumor Cells and Binding Affinity for Human Estrogen Receptor [Alpha]

To examine the estrogenic activities of styrene oligomers, we carried out cell proliferation assays with estrogen-sensitive MCF-7 cells and competitive binding assays to human estrogen receptor [Alpha] (hER[Alpha]) he styrene oligomers tested were 1,3-diphenyl propane (SD-1), 2,4-diphenyl-1-butene (SD-2), cis-1,2-diphenyl cyclobutane (SD-3), trans-1,2-diphenyl cyclobutane (SD-4), 2,4,6-triphenyl-1-hexene (ST-1), 1a-phenyl-4a-(1'-phenylethyl)tetralin (ST-2), 1a-phenyl-4e-(1'-phenylethyl)tetralin (ST-3), 1e-phenyl-4a-(1'-phenylethyl)tetralin (ST-4), 1e-phenyl-4e-(1'-phenylethyl)tetralin (ST-5), 1e,3e,5a-triphenylcyclohexane (ST-6), and 1e,3e,5e-triphenylcyclohexane (ST-7). In the MCF-7 cell proliferation assay, styrene trimers (ST-1, ST-3, ST-4, and ST-5) had the highest proliferative activities of the compounds tested. The relative potency of these chemicals was 0.0002-0.0015%, which was comparable with that of bisphenol A (0.0001-0.0025%), and their relative proliferative effect was 51-104%. Styrene dimers (SD-3 and SD-4) also significantly increased the cell yields. However, SD-1, SD-2, ST-2, ST-6, and ST-7 had insignificant proliferative activities. The competitive binding assay revealed the binding affinity of some styrene oligomers for hER[Alpha]. The order of their binding potency for hER[Alpha] was as follows: ST-4 [is greater than] ST-2 [is greater than] ST-3 [is greater than] ST-5 [is greater than] ST-1 [is greater than] SD-3 [is greater than] SD-4 [is greater than] SD-2 [is greater than] SD-1. ST-6 and ST-7 did not appear to bind to hER[Alpha]. The present studies indicate that styrene dimers SD-3 and SD-4 and styrene trimers ST-1, ST-3, ST-4, and ST-5 have estrogenic activity on MCF-7 cells and binding affinity for hER[Alpha]. These compounds might be endocrine disrupters. Key words: binding affinities, cell proliferative activities, estrogenic activities, human estrogen receptor [Alpha], MCF-7 cells, styrene oligomers.

Environ Health Perspect 109:699-703 (2001). [Online 29 June 2001] http://ehpnet1.niehs.nih.gov/docs/2001/109p699-703ohyama/abstract.html

Polystyrene used for food containers, such as takeout food containers, coffee cups, meat trays, soup bowls, and salad boxes (1), contains high levels of styrene dimers (90-1,030 [micro]g/g) and styrene trimers (650-20,770 [micro]g/g) as impurities (2,3). These styrene oligomers migrate from the polystyrene containers into the containers' contents (4-6). When polystyrene containers containing vegetable oil were treated by heating in a microwave oven or were incubated for 24 hr at 20 [degrees] C, a styrene dimer, 2,4-diphenyl-1-butene (SD-2; 0-1.6 ng/[cm.sup.2]) and styrene trimers 2,4,6-triphenyl-1-hexene (ST-1; 1.3-69.7 ng/[cm.sup.2]), 1a-phenyl-4a-(1'-phenylethyl)tetralin (ST-2; 9.2-156 ng/[cm.sup.2]), 1a-phenyl-4e-(1'-phenylethyl)tetralin (ST-3; 18.1-501 ng/[cm.sup.2]), 1e-phenyl-4a-(1'-phenylethyl)tetralin (ST-4; 13.9-294 ng/[cm.sup.2]), and 1e-phenyl-4e-(1'-phenylethyl)tetralin (ST-5; 18.7-306 ng/[cm.sup.2]) migrated into the vegetable oil (4). When instant foods such as Chinese noodles, Japanese noodles, buckwheat noodles, chow mein, spaghetti, and rice were packed in polystyrene containers, styrene trimers ST-1 (0-8.1 [micro]g/cup), ST-2 + ST-3 (0-13.8 [micro]g/cup), ST-4 (0-5.2 [micro]g/cup), and ST-5 (0-8.4 [micro]g/cup) migrated (0-33.8 [micro]g total styrene oligomers detected in a cup) from the containers into the foods after cooking in the cups, but the dimers did not (5). The maximum quantity of styrene trimers that migrated from containers to foods was higher than that of bisphenol A leached from the lacquer coating of vegetable cans (4-23 [micro]g/can) (7).

Colborn et al. (8) designated styrene dimers and trimers as endocrine disrupters in the Wingspread statement, and the Environmental Agency, Government of Japan, cited styrene dimers and trimers as compounds suspected of having endocrine-disruptive effects in its Strategic Programs on Environmental Endocrine Disrupters (9). However, styrene oligomers were reported to have no endocrine disruptive effect both in a MCF-7 cell proliferation assay (10) and in a radioisotope (RI) receptor competitive-binding assay using rat estrogen receptor (10,11). Therefore, we tested 11 styrene oligomers including those found in food (4,5) in a proliferation assay at an optimal initial cell concentration using human breast tumor, highly estrogen-sensitive MCF-7 cells. We also examined the binding potency of these styrene oligomers to human estrogen receptor [Alpha] (hER[Alpha]) in a non-RI receptor competitive-binding assay.

Materials and Methods

Chemicals. The styrene dimers 1,3-diphenyl propane (SD-1), SD-2, cis-1,2-diphenyl cyclobutane (SD-3), and trans-1,2-diphenyl cyclobutane (SD-4) and styrene trimers ST-1, ST-2, ST-3, ST-4, ST-5, 1e,3e,5a-triphenylcyclohexane (ST-6), and 1e,3e,5e-triphenylcyclohexane (ST-7) were purchased from Hayashi Pure Chemical Industry. (Osaka, Japan). The positive control, 17[Beta]-estradiol ([E.sub.2]), was obtained from Calbiochem (Richmond, CA, USA). The chemical structures of these compounds are shown in Figure 1, and the purity of the compounds is summarized in Table 1.

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Table 1. Data on tested chemicals

                Original
            concentration (mM)

            Ethanol    DMSO
             solu-     solu-                             Purity
Compound    tion(a)   tion(b)   Supplier (code no.)      (%)(c)

[E.sub.2]    0.001      0.1     Calbiochem (3301)        > 99.5
SD-1          10        100     Hayashi PC (990-52331)     97.9
SD-2          10        100     Hayashi PC (990-52334)     99.0
SD-3          10        100     Hayashi PC (990-52332)     99.9
SD-4          10        100     Hayashi PC (990-52333)     99.4
ST-1          10        10      Hayashi PC (990-52335)     98.2
ST-2           1         1      Hayashi PC (990-52336)     98.2
ST-3          10        10      Hayashi PC (990-52337)     99.9
ST-4          10        10      Hayashi PC (990-52338)     99.5
ST-5          10        10      Hayashi PC (990-52339)     99.2
ST-6          10        3.6     Hayashi PC (990-52387)     99.6
ST-7           1        10      Hayashi PC (990-52388)     99.5

(a) Ethanol solution was used for MCF-7 cell proliferation assay.
(b) DMSO solution was used for competitive binding assay.
(c) purity of the chemicals as reported by the suppliers.

Solvent for styrene oligomers. Styrene oligomers and [E.sub.2] were dissolved in ethanol for the MCF-7 cell proliferative assay. Styrene oligomers were dissolved in ethanol at the concentration of [10.sup.-2] M, except for ST-2 and ST-6, which were dissolved at [10.sup.-3] M due to the lower solubility of these compounds. The cell proliferation assay was performed at [is less than or equal to] [10.sup.-5] M styrene oligomers.

For a competitive binding assay, styrene oligomers and [E.sub.2] were dissolved in dimethyl sulfoxide (DMSO). The assay was performed at [is less than or equal to] 5 x [10.sup.-3] M styrene oligomers. Glass Pasteur capillary pipettes were used in handling the chemical solutions.

Culture medium. Dulbecco's modification of Eagle's Medium (DME) containing phenol red and fetal bovine serum (FBS) were purchased from Nissui (Tokyo, Japan) and Hyclone (Logan, UT, USA), respectively. Phenol red-free DME (Cat. no. 23800-022) was obtained from Gibco BRL (Grand Island, NY, USA)

Removal of sex steroids by charcoal-dextran treatment of serum. We removed sex steroids from FBS by charcoal-dextran stripping (CDFBS) (12). Charcoal and dextran T70 were purchased from Sigma (St. Louis, MO, USA) and Amersham Pharmacia Biotech (Uppsala, Sweden), respectively.

Cell line and cell culture conditions. Estrogen-sensitive human breast tumor MCF-7 cells were provided by Ana M. Soto (Tufts University School of Medicine, Boston, MA, USA). For routine maintenance, cells were grown in 5% FBS medium (DME with phenol red supplemented with 80 mg/L kanamycin, 50 mg/L gentamycin, 4 mM L-glutamine, 2.24 g/L sodium hydrogen carbonate, and 5% FBS) in an atmosphere of 5% C[O.sub.2]/95% air with saturating humidity at 37 [degrees] C. Cells were subcultured every 2 weeks. The cells detached by 0.05% trypsin were plated at an initial concentration of 12,500 cells/mL. The 5% FBS medium in the cell cultures was replaced with fresh medium twice a week.

MCF-7 cell proliferation assay. Phenol red-free DME 8.3 g/L was supplemented with 1 g/L glucose, 110 mg/L sodium pyruvate, 80 mg/L kanamycin, 50 mg/L gentamycin, and 12 mM HEPES (plain DME). The 5% CDFBS medium for proliferation assay consisted of plain DME, 4 mM L-glutamine, 2.24 g/L sodium hydrogen carbonate, and 5% CDFBS. The E-SCREEN assay to evaluate MCF-7 cell proliferation was performed according to a technique modified from that originally described by Soto et al. (13). Briefly, MCF-7 cells cultured for 11 days were trypsinized and plated in 24-well plates (Falcon, Franklin Lakes, NJ, USA) at an initial concentration of 40,000 cells/mL of 5% FBS medium/well. After the cells were allowed to attach for 24 hr, 0.9 mL of 5% CDFBS medium was substituted for the seeding medium. The solution of chemicals in ethanol was diluted with plain DME to various concentrations, and 0.1 mL of that was added in wells. The ethanol concentration in culture medium did not exceed 0.1%. The cells were cultured for 6 days in an atmosphere of 5% [CO.sub.2]/95% air with saturating humidity at 37 [degrees] C. The medium was not changed at all over the course of the experiment. The assay was terminated by removing the medium from wells. We calculated the number of cells by measuring the amount of protein stained with sulforhodamine-B (SRB; Wako PC, Osaka, Japan) as described by Brotons et al. (7) and Villalobos et al. (14). In this assay, the cell yield in [10.sup.-10] M [E.sub.2] was 3.6-fold (SD = 0.825) higher than the solvent control. Differences between the values obtained in the presence of the test chemicals and those obtained in the solvent controls were assessed using the Newman-Keuls test. A p-value of [is less than] 0.01 was regarded as significant.

Competitive binding assay. The binding potency of test chemicals to hER[Alpha] was measured by non-RI receptor binding assay using the Estrogen-R([Alpha]) Competitor Screening Kit (Wako PC) according to the manufacturer's instructions. Briefly, the test chemical dissolved in DMSO and other reagents including fluorescence-labeled [E.sub.2] were mixed and competitively bound to the hER[Alpha] coated on the microplate wells (15). DMSO was not effective in this assay. The fluorescence intensity was measured at excitation (485 nm) and emission (535 nm) with a fluorescence microplate reader apparatus, Spectra Fluo (Tecan, Austria). We calculated the binding levels of the chemicals to hER[Alpha] from the decrease of fluorescence intensity.

Results

MCF-7 cell proliferation assay. We compared the increase of cell yield obtained at different concentrations of test chemicals with that obtained in [10.sup.-10] M [E.sub.2] (Figure 2). The increase of cell yield with [10.sup.-10] M [E.sub.2] (= the cell yield in [10.sup.-10] M [E.sub.2] -- the cell yield in the solvent control) was expressed as 100%. Data were expressed as the means [+ or -] SDs of three independent assays performed in triplicate. This cell proliferation assay was performed at [is less than or equal to] [10.sup.-5] M styrene oligomers because of low solubility in culture media. E[C.sub.50] is the concentration of test compound that produces 50% of the increase of cell yield by [10.sup.-10] M [E.sub.2]. The values of relative potency (RP), defined as the ratio of the E[C.sub.50] of [E.sub.2] to that of the test compound, and the values of relative proliferative effect (RPE), defined as the ratio of the highest increase of cell yield obtained with the test compound to that with [10.sup.-10] M [E.sub.2], are shown in Table 2. Results are summarized below:

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Table 2. Estrogenic effects of styrene oligomers.

                   MCF-7 cell proliferation assay

Compound       [EC.sub.50] (M)(a)   RP (%)(b)    RPE (%)(c)

[E.sub.2]      1.4 x [10.sup.-11]      100          100
SD-1                   NE               --           --
SD-2                   NE               --           --
SD-3                 R < 50             --           31
SD-4                 R < 50             --           29
ST-1           9.5 x [10.sup.-7]      0.0015         81
ST-2                   NE               --           --
ST-3           2.9 x [10.sup.-6]      0.0005         86
ST-4           2.3 x [10.sup.-6]      0.0006        104
ST-5           9.5 x [10.sup.-6]      0.0002         51
ST-6                   NE               --           --
ST-7                   NE               --           --

               Competitive binding assay

Compound    [IC.sub.20] (M)(d)   RBA (%)(e)

[E.sub.2]   6.0 x [10.sup.-11]      100
SD-1        1.2 x [10.sup.-4]      0.005
SD-2        7.6 x [10.sup.-5]      0.008
SD-3        2.4 x [10.sup.-6]      0.025
SD-4        5.6 x [10.sup.-6]      0.011
ST-1        1.2 x [10.sup.-5]      0.05
ST-2        6.2 x [10.sup.-6]      0.097
ST-3        9.7 x [10.sup.-6]      0.062
ST-4        2.6 x [10.sup.-6]      0.228
ST-5        1.0 x [10.sup.-6]      0.058
ST-6                NE               --
ST-7                NE               --

(a) [EC.sub.50], the concentration of test compound producing 50%
of the increase of cell yield by [10.sup.-10] M [E.sub.2]; NE, value
could not be estimated from the response curve; R < 50, maximal
response observed for the test chemical at the concentrations
tested was below 50%. (b) RP = [([EC.sub.50] of [E.sub.2]) /
([EC.sub.50] of the test compound)] x 100. (c) RPE = [(the highest
cell yield obtained with the test compound) / (the cell yield
obtained with the solvent control)-1] + [(the cell yield obtained
with [10.sup.-10] M [E.sub.2]) / (the cell yield obtained with the
solvent control) -1] x 100. (d) [IC.sub.20] = the concentration of
test chemicals for 20% inhibition of binding of fluorescence-labeled
[E.sub.2] to ER[Alpha]. (e) RBA = ([IC.sub.20] of [E.sub.2]) /
([IC.sub.20] of the test compound) x 100.

* SD-1 and SD-2: No effect was observed at [10.sup.-8], [10.sup.-7], and [10.sup.-6] M; however, a slight increase of cell yield was found in [10.sup.-5] M.

* SD-3: Significant cell proliferation (p [is less than] 0.01) was induced by this compound at [is greater than or equal to] [10.sup.-6] M, and the highest cell yields were obtained at [10.sup.-5] M. RPE was 31%.

* SD-4: A slight increase in cell yield appeared at [10.sup.-6] M, and significant cell proliferation (p [is less than] 0.01) was induced by this chemical at [10.sup.-5] M; RPE was 29%.

* ST-1: Significant cell proliferation (p [is less than] 0.01) was induced at [is greater than or equal to] [10.sup.-6] M. The highest cell yields were obtained at [10.sup.-5] M; therefore, RP and RPE were 0.0015% and 81%, respectively.

* ST-2: The cell yield decreased at [10.sup.-8] and [10.sup.-7] M compared to that in the solvent control. A slight increase in cell yields was found at [10.sup.-6] M; at [is greater than] [10.sup.-5] M, the effect on proliferation could not be examined due to the insolubility of this chemical.

* ST-3: Significant cell proliferation (p [is less than] 0.01) was induced by this chemical at [is greater than or equal to] [10.sup.-6] M, and the highest cell proliferation was observed at [10.sup.-5] M. RP and RPE were 0.0005% and 86%, respectively.

* ST-4: Significant cell proliferation (p [is less than] 0.01) was induced at [10.sup.-6] M, and the highest cell proliferation was observed at [10.sup.-5] M. RP and RPE were 0.0006% and 104%, respectively, the highest of the tested styrene oligomers.

* ST-5: An increase in cell yields was seen from [10.sup.-6] M, and significant cell proliferation (p [is less than] 0.01) was caused by this compound at [10.sup.-5] M. RP and RPE were 0.0002% and 51%, respectively.

* ST-6 and ST-7: These chemicals decreased cell yields.

Binding of styrene oligomers to hER[Alpha]. The inhibition of the binding of fluorescence-labeled [E.sub.2] to hER[Alpha] by various concentrations of tested compounds is shown in Figure 3. The inhibition by styrene dimers (SD-1, SD2, SD-3, and SD-4) was detected at [is greater than or equal to] 5 x 10-5 M, and was concentration dependent. The maximum inhibition was 51-76% by each compound at 5 x 10-4 M. The inhibition by styrene trimers (ST-1, ST-2, ST-3, ST-4, and ST-5) was detected at [is greater than or equal to] 5 x [10.sup.-6] M. This concentration (5 x [10.sup.-6] M) was lower by one order of magnitude than the concentrations of styrene dimers that caused comparable inhibition. However, complete inhibition could not be obtained. The maximum inhibition was 28-44% at 5 x [10.sup.-5] M. Inhibition by [E.sub.2] as a positive control was detected starting at the lower concentration of 5 x [10.sup.-9] M and was concentration dependent. [E.sub.2] at 5 x [10.sup.-7] M caused 86% inhibition. A slight inhibition by ST-6 was seen at 1.8 x [10.sup.-5] M. ST-7 could not cause inhibition at any concentration. Styrene trimers were insoluble at [is greater than] 5 x [10.sup.-4] M in the reaction solution containing fluorescence-labeled [E.sub.2]. The concentration for 20% inhibition of the binding ([IC.sub.20]) and the ratio of [IC.sub.20] of [E.sub.2] to that of each styrene oligomer (relative binding affinity; RBA) are shown in Table 2. The RBAs of styrene dimers SD-1, SD-2, SD-3, and SD-4 were 0.005, 0.008, 0.025, and 0.011%, respectively, and those of styrene trimers ST-1, ST-2, ST-3, ST-4, and ST-5 were 0.05, 0.097, 0.062, 0.228, and 0.058%, respectively. The styrene trimers, except for ST-6 and ST-7, had relatively high affinity for hER[Alpha].

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Discussion

We demonstrated that proliferation of MCF-7 cells was induced by styrene oligomers such as SD-3, SD-4, ST-1, ST-3, ST-4, and ST-5. The maximal proliferation occurred at a [10.sup.-5] M concentration of styrene oligomers. ST-1, ST-3, ST-4, or ST-5 produced complete concentration-response curves up to [10.sup.-5] M in the MCF-7 cell proliferation assay. ST-4 had the highest proliferative activity among the tested styrene oligomers and was a full agonist. ST-1, ST-3, and ST-5 had relatively high activity (RPE = 51-81%). The RP of styrene trimers ST-1, ST-3, ST-4, and ST-5 was 0.0002-0.0015% in the MCF-7 cell proliferation assay; these values were comparable to that of bisphenol A (0.0001-0.0025%) (16) and higher than that of 4-n-nonylphenol (RP = 0.000008-0.00007%) (16). The proliferative activities of styrene dimers were weaker than those of styrene trimers. Nobuhara et al. (10) reported that SD-3, SD-4, ST-1, and a mixture of tetralin ring trimers were not able to induce the proliferation of MCF-7 cells. They used MCF-7 cells (American Type Culture Collection; ATCC) purchased from Dainippon P. (Osaka, Japan) at an initial cell concentration of 2 x [10.sup.4] cells/well in 12-well plates. Villalobos et al. (14) reported that MCF-7 supplied by A.M. Soto had the highest proliferative response to [E.sub.2], and that the ATCC strain responded to [E.sub.2] with a much smaller increase in cell yield. They also reported that ATCC MCF-7 cells should not be used in cell proliferation tests such as the E-SCREEN assay (14). Our results were obtained using MCF-7 cells provided by A.M. Soto at an initial concentration of 4 x 104 cells/well in 24-well plates. We confirmed that the initial concentration of 4 x [10.sup.4] cells/well in 24-well plates was optimal for cell proliferation assays and a concentration [is less than] 2 x [10.sup.4] cells/well in 24-well plates tended to increase the minimal concentration of test compound needed for maximal cell yield and the value of E[C.sub.50] (17).

Styrene trimers such as ST-1, ST-2, ST-3, ST-4, and ST-5 and styrene dimers such as SD-1, SD-2, SD-3, and SD-4 had binding affinity for hER[Alpha]. RBAs of ST-1, ST-3, ST-4, and ST-5 were higher than those of SD-1, SD-2, SD-3, and SD-4, although the high affinity for hER[Alpha] was revealed at 5 x [10.sup.-4] M styrene dimers. It seems that styrene trimers at [is greater than or equal to] 5 x [10.sup.-5] M had low solubility in the reaction solution. We found that the binding potency of styrene trimers except for ST-6 and ST-7 were higher than that of styrene dimers. ST-2 had binding affinity for hER[Alpha] and the RBA was higher than that of ST-1, ST-3, and ST-5, which had strong proliferative activity, although the proliferative activity was not significant. ST-2 may be estrogenic, although the proliferative activity could not be ascertained due to extremely low solubility in the solvent for the MCF-7 cell proliferation assay. We do not think that ST-6 and ST-7 are estrogenic because the values could not be estimated from the response curves in the cell proliferative assay and the competitive binding assay.

Azuma et al. (11) and Nobuhara et al. (10) reported that SD-1, SD-3, SD-4, ST-1, ST-2, ST-3, and ST-5 had no affinity for ER in an RI competitive binding assay. Although they examined the binding affinity of styrene oligomers at [is less than or equal to] [10.sup.-5] M for ER of rat uterus, we tested them at the concentrations up to 5 x [10.sup.-3] or 5 x [10.sup.-4] M for purified human ER [Alpha]. If they had tested at a concentration [is greater than] 5 x [10.sup.-5] M, the binding activity would have been observed.

Estrogenic activities of styrene trimers differed depending on their chemical structures. Styrene trimers with a linear structure (ST-1) and a tetralin structure (ST-2, ST-3, ST-4, and ST-5) had estrogenic activity, but those with a cyclohexane structure (ST-6 or ST-7) did not.

The value of RPE from the MCF-7 cell proliferation assay correlated with the value of RBA from the competitive binding assay. This result suggested that the cell proliferative effect of these styrene oligomers was caused by their binding to hER[Alpha].

Styrene trimers such as ST-1, ST-3, ST-4, and ST-5 tested here moved from containers into foods upon heat treatment, preservation for 24 hr at 20 [degrees] C, or cooking (3,4), and they are incorporated into the body with the foods. The present study demonstrated that styrene oligomers, particularly styrene trimers such as ST-1, ST-3, ST-4, and ST-5, had relatively high estrogenic activities in the MCF-7 cell proliferation assay and the competitive binding assay. These compounds might be endocrine disrupters. The effects of styrene trimers on uteri have not been found in in vivo studies using 21-day-old rats (10). However, fetuses are more vulnerable to estrogenic chemicals than are adults. The hormonal effects of these styrene trimers with regard to reproduction and the nervous system should be investigated using experimental animals, particularly in embryos.

REFERENCES AND NOTES

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(13.) Soto AM, Lin TM, Justicia H, Silvia RM, Sonnenschein C. An "in culture" bioassay to assess the estrogenicity of xenobiotics (E-screen). In: Chemically-induced Alterations in Sexual and Functional Development: the Wildlife/human Connection, Vol 21 (Colborn T, Clement C, eds). Princeton, NJ:Princeton Scientific Publishing, 1992;295-309.

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(15.) Nishibe T, Hirayasu K, Date M, Tanaka I. A simple assay for endocrine disrupters by using hER[Alpha] immobilized microplate and fluorescence labeled estradiol. 2nd Annual Meeting of Japan Society of Endocrine Disrupter Research, 9-10 December 1999, Kobe, Japan. Tsukuba, Japan:Japan Society of Endocrine Disrupters Research, 1999;15.

(16.) Andersen HR, Andersson A-M, Arnold SF, Autrup H, Barfoed M, Beresford NA, Bjerregaard P, Christiansen LB, Hummel R, Jorgensen EB, et al. Comparison of short-term estrogenicity tests for identification of hormone-disrupting chemicals. Environ Health Perspect 107(suppl 1):89-108 (1999).

(17.) Ohyama K, Hamaoka A, Yamamoto T, Takeuchi M, Tsuchiya Y. Effects of initial cell concentration on E-SCREEN assay. Ann Rep Tokyo Metr Res Lab PH 51:239-242 (2000).

Address correspondence to K. Ohyama, Department of Environmental Health, Tokyo Metropolitan Research Laboratory of Public Health, 24-1, Hyakunincho 3 chome, Shinjuku-ku, Tokyo 169-0073, Japan. Telephone: 81-3-3363-3231. Fax: 81-3-3368-4060. E-mail: ohyama@tokyo-eiken.go.jp

We thank A. Hamaoka and T. Yamamoto for technical assistance.

Received 6 December 2000; accepted 5 February 2001.

Ken-ichi Ohyama,(1) Fumiko Nagai,(1) and Yoshiteru Tsuchiya(2)

(1) Department of Environmental Health, Tokyo Metropolitan Research Laboratory of Public Health, Tokyo, Japan; (2) Department of Applied Chemistry, Kogakuin University, Tokyo, Japan

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