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Developmental Exposure to Polychlorinated Biphenyls Exerts Thyroid Hormone-Like Effects on the Expression of RC3/Neurogranin and Myelin Basic Protein Messenger Ribonucleic Acids in the Developing Rat Brain¹

Biology Department, University of Massachusetts, Morrill Science Center, Amherst, Massachusetts 01003

Address all correspondence and requests for reprints to: R. Thomas Zoeller, Ph.D., Biology Department, University of Massachusetts, Morrill Science Center, Amherst, Massachusetts 01003.

	Abstract

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Polychlorinated biphenyls (PCBs) are a class of industrial compounds consisting of paired phenyl rings with various degrees of chlorination. They are now ubiquitous, persistent environmental contaminants that are routinely found in samples of human and animal tissues and are known to affect brain development. The effects of PCBs on brain development may be attributable, at least in part, to their ability to reduce circulating levels of thyroid hormone. However, the developmental effects of PCB exposure are not fully consistent with hypothyroidism. Because some individual PCB congeners interact strongly with various thyroid hormone binding proteins, several investigators have speculated that these congeners may be producing thyroid hormone-like effects on brain development. Therefore, we tested whether a mixture of PCBs, Aroclor 1254 (A1254), would produce an antithyroid or thyromimetic effect on the expression of known thyroid hormone-responsive genes in the developing brain. Pregnant female rats were fed various doses of A1254 (0, 1, 4, and 8 mg/kg) from gestational day 6 to weaning on postnatal day (P) 21. Pups derived from these dams were sampled on P5, P15, and P30. Total T₄ was reduced by A1254 in a dose-dependent manner, but body weight of the pups or dams was not affected. The expression of RC3/Neurogranin and myelin basic protein was not affected by A1254 on P5 or P30. However, on P15, RC3/Neurogranin was elevated by A1254 in a dose-dependent manner, and myelin basic protein expression followed this general pattern. These data clearly demonstrate that the developmental effects of PCB exposure are not simply a function of PCB-induced hypothyroidism.

	Introduction

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POLYCHLORINATED BIPHENYLS (PCBs) are a class of industrial compounds consisting of paired phenyl rings with various degrees of chlorination (1). Before their production was banned in the 1970s, over a billion kilograms of PCBs were produced (2); and they are now ubiquitous, persistent environmental contaminants that are routinely found in samples of human and animal tissues (1, 3). PCBs become concentrated especially in fatty tissues because they are highly lipophilic. The observation that PCBs become concentrated in human milk is particularly concerning because concentrations of individual congeners reported for milk samples taken from women exposed to local background PCB levels and actively breast-feeding their infants range from 38.3 ng/g lipid (4) to 395 ng/g lipid (5), corresponding to approximately 1.28 µg/ml milk (3.52 µM) to 13.2 µg/ml milk (36.3 µM) (6). Thus, the potential magnitude of PCB exposure to infants through breast milk and other sources justifies concern about potential effects on development.

PCBs are known to be developmental neurotoxicants at environmentally-relevant concentrations (7, 8, 9, 10, 11). The most commonly noted neurological abnormalities associated with low-levels of PCB contamination in humans are hypoactivity and impaired learning (3). Because the symptoms of PCB exposure can overlap with those of thyroid dysfunction, several investigators have speculated that the neurological consequences of incidental exposure to PCBs are caused by disruption of the thyroid axis (12, 13). Many reports document that PCBs reduce circulating levels of thyroid hormone (reviewed by Refs. 13, 14, 15), an effect believed to be produced by the simultaneous activation of liver UDP-glucuronosyltransferase involved in thyroid hormone metabolism (16) and displacement of T₄ from serum proteins (14). These two effects seem to interact to produce a significant reduction in circulating levels of total and free T₄, and total and free T₃ (14, 17, 18, 19). These observations have lead to the prediction that PCBs effectively produce neurological deficits by producing hypothyroidism. Several lines of evidence support this prediction. For example, PCB exposure reduces circulating levels of thyroid hormone and produces hearing loss in rats (18) that can be partially ameliorated by T₄ administration (20). In addition, T₄ can normalize the PCB-induced suppression of choline acetyltransferase activity in the forebrain of neonatal rats (21). Finally, perinatal PCB exposure can increase testis size of the adult rat (22), an effect that is identical to that of perinatal treatment with goitrogens (23).

However, the structure of some PCB congeners may resemble that of thyroid hormone enough to interact with the thyroid hormone receptor (TR) (24), acting as agonists, antagonists, or mixed agonists (25). This hypothesis also is supported by several lines of evidence. For example, PCB exposure does not produce a compensatory increase in circulating TSH, despite profound hypothyroxinemia (reviewed in Refs. 14, 16), suggesting that unidentified individual PCB congeners are suppressing TSH (14, 16). In addition, developmental exposure to PCBs advances the onset of eye opening in rats (18), an event associated with hyperthyroidism. In humans, children exposed to high levels of PCBs can exhibit hyperactivity (26), a symptom that also may be associated with subclinical hyperthyroidism (27). Finally, Cheek et al. (28) have recently shown that some individual PCB congeners can bind to the human TRß1. These studies support the speculation that individual PCB congeners can directly interact with TRs.

The hypothesis that individual PCB congeners are interacting with the TR suggests that the effects of PCBs on brain development may not be purely a function of PCB-induced hypothyroxinemia. To test this hypothesis, we examined whether PCBs produce antithyroid or thyromimetic effects on specific thyroid hormone-responsive gene expression in the developing brain. TRs are hormone-activated transcription factors (29, 30) that regulate the expression of specific genes in the brain during development (31, 32, 33). Therefore, we focused on two well-characterized thyroid hormone-responsive genes, RC3/Neurogranin (34) and myelin basic protein (MBP) (35, 36, 37).

	Materials and Methods

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Animal treatment
All procedures were performed in accordance with the NIH guidelines for the ethical treatment of animals and were approved by the University of Massachusetts-Amherst Institutional Animal Care and Use Committee before initiating these studies.

Timed-pregnant Sprague Dawley rats (n = 33) were purchased from Zivic-Miller Laboratories, Inc. (Pittsburgh, PA) and arrived in our animal facility 2 days after insemination [gestational day (GD)2]. They were individually housed in plastic cages, were provided with food and water continuously, and were maintained on a 12-h light, 12-h dark cycle (0600 h–1800 h). Beginning on the day of arrival, each dam was weighed in the morning and provided with a single wafer 1 h before lights off. This initial training period (GD2–GD6) was required for the animals to consume a wafer quickly during the experimental procedure. Beginning on GD6 and continuing until weaning on postpartum day (P) 21, the dams were weighed in the morning and provided daily with a wafer dosed with 50 µl/100 g BW of a solution calibrated to deliver specific doses of a commercial mixture of PCBs [Aroclor 1254 (A1254); AccuStandard, Inc., New Haven, CT]. Wafers were individually dosed each morning based on the dam’s weight. PCBs were dissolved in contaminant-free methanol, pipetted onto the wafer, and allowed to dry in a fume hood throughout the day before feeding. Control wafers (0 mg/kg PCB) were dosed with methanol alone. Doses of A1254 included 0, 1.0, 4.0, and 8.0 mg/kg BW. Because earlier reports indicated that daily administration of 8 mg/kg A1254 may reduce the rate at which body weight increases in pregnant rats (18), we measured food consumption by dams in the 8-mg/kg group and pair-fed an additional control group (0-mg/kg) to this amount of food. However, we found no differences in food consumption or body weight in the 8-mg/kg group. Therefore, our control group (0-mg/kg) contains twice the number of animals as PCB-treated groups (n = 12 vs. n = 6, respectively).

On P5, P15, and P30, one pup from each litter was weighed and killed by decapitation. Trunk blood was collected for measurement of serum total T₄. The head (P5) or brain (P15 and P30) was frozen in pulverized dry ice, labeled, and stored at -80 C until it was sectioned for in situ hybridization. Additionally, one pup from each litter was also weighed and killed on P1, P10, and P20 for measurement of serum T₄. Only males were included on P30. A follow-up study in which male and female pups were compared for their responses to A1254 exposure on P5 and P15 revealed no treatment effects on body weight or thyroid hormone (data not shown).

In situ hybridization
Frozen brain tissues were sectioned in coronal plane at 12 µm in a cryostat (Reichert-Jung Frigocut 2800N, Leica Corp., Deerfield, IL). Coronal sections were made through the rostral hippocampus at approximately 2.8–3.8 mm caudal to bregma, corresponding to Figs. 29–33 of Paxinos and Watson (38), and through the cerebellum at approximately 12.72–13.68 mm caudal to bregma, corresponding to Figs. 68–72. Sections were thaw-mounted onto cold gelatin-coated microscope slides and stored at -80 C until hybridization. Prehybridization treatments, hybridization, and posthybridization washes were carried out for RC3/Neurogranin as described earlier (39), with a few exceptions as follows. First, the sections were immersed for 30 min in 4% formalin, and the hybridization was performed at 52 C. Second, the hybridization buffer did not contain single-stranded DNA. Finally, the ribonuclease treatment, after hybridization, was performed in a buffer containing 10 mM Tris/1 mM EDTA/2 x SSC, at pH 7.4. The in situ hybridization protocol for MBP messenger RNA (mRNA) was performed as described (40), except that the hybridization buffer contained 200 mM dithiothreitol.

Probe preparation
The RC3 RNA probes (complementary or sense-strand) were generated in vitro from an RC3 cDNA, kindly provided by Dr. Juan Bernal [pPRC/CMV-RC3 (34), Madrid, Spain]. The transcription reaction was performed in a final vol of 10 µl. RNA was synthesized in the presence of 1 µg DNA template (linearized plasmid); 500 µM each of GTP, ATP, and CTP; and 12 µM UTP (UTP + ³³P-UTP at a molar ratio of 1:1). pPRC/CMV-RC3 was linearized with HindIII and transcribed in the presence of SP6 RNA polymerase for complementary RNA production. After transcription, the DNA template was removed by deoxyribonuclease digestion, and the probe was purified by phenol(-)chloroform extraction followed by two ethanol precipitations. The size and integrity of the ³³P- RC3 probe (337 bp) was verified on a 6% sequencing gel. The probe used to quantify MBP mRNA was an oligonucleotide that we have previously characterized (40). This 48-base oligonucleotide was labeled with ³³P-deoxy-ATP using terminal deoxynucleotidyl transferase, as previously described (40).

Autoradiography and signal quantitation
Slides were arranged in x-ray cassettes and apposed to BioMax film (Eastman Kodak Co., Rochester, NY) for periods that depended on the specific activity of the probe and the abundance of the target message. For RC3/Neurogranin mRNA, these periods were 24 h, 15 h, and 17 h for P5, P15, and P30, respectively. For MBP mRNA, these periods were 10 days, 4 days, and 3 days for P5, P15, and P30, respectively. ¹⁴C-standards (American Radiolabeled Chemicals, Inc., St. Louis, MO) were simultaneously apposed to the film to ensure that the film was not overexposed. For RC3/Neurogranin in P15 brains, the slides were dipped in Eastman Kodak Co. NTB-3 nuclear tract emulsion after film autoradiography. These emulsion autoradiograms were developed in Dektol, fixed in Eastman Kodak Co. Fixer, and counterstained with Methyl Green (Sigma, St. Louis, MO).

Regional analysis of gene expression was performed as follows. First, a 5x magnified image was captured using a Scion AG-5 capture board interfaced with the public domain NIH-Image 1.61/ppc (W. Rasband, National Institute of Mental Health, Bethesda, MD) being run on a Macintosh 7600. The optical system included a Dage-MTI 72 series video camera equipped with a Nikon macro lens mounted onto a bellows system over a light box. The relative level of expression of RC3/Neurogranin mRNA was measured by microdensitometry, in which the area of the specific brain region and the film density was measured. Brain areas included the occipital cortex (Oc2) (medial and lateral aspects of layer 2), retrosplenial granular cortex (RSG), piriform cortex (Pir), dentate gyrus (DG), CA1, CA2, and CA3 subfields of Ammon’s horn (see Fig. 4C). The RSG, Pir, and DG have been shown previously to be areas in which RC3/Neurogranin expression is affected by thyroid hormone (34). For RC3/Neurogranin expression, the signal was evaluated using the greyscale setting by encircling the target brain region and acquiring the area of the identified region and the average density of that area of film. The density value was corrected by subtracting the density of an adjacent area of film. MBP expression was measured on film separately over the entire cerebellum or the entire pons/medulla (Fig. 1B) using a threshold value that allowed us to electronically subtract background. This was required because of the striated nature of MBP expression in the cerebellum (see Fig. 4D). For both RC3/Neurogranin and MBP, the resulting values were averaged over four sections from each brain. Measurements were taken by two independent operators who were unaware of the identify of the signals. Concordance between operators was always observed.

View larger version (102K): [in this window] [in a new window]   Figure 4. Film autoradiograms after in situ hybridization for RC3/Neurogranin mRNA (A, C, E, and G) and MBP mRNA (B, D, F, and H). A–F were taken from control animals. G and H represents a composite to illustrate the difference in signal intensity between control animals (left side of panel) and those treated with 8 mg/kg A1254 (right side) for RC3 and MBP, respectively. Arrowheads identify regions that were significantly more intense in PCB-treated animals. Note that MBP mRNA was not detected in the cerebellum of P5 animals (B). Scale bar = 1.0 cm; A–F and G–H have the same magnification, respectively.

View larger version (36K): [in this window] [in a new window]   Figure 1. Effect of A1254 on body weight of dams (grams) during the period of treatment. Dams were treated daily with different doses of A1254 as shown in the legend. No significant effect of treatment was observed (F(treatment)3,312 = 0.666; P = 0.5810).

View larger version (31K): [in this window] [in a new window]   Figure 7. MBP mRNA levels in the cerebellum and medulla of pups derived from dams treated with different doses of A1254. Bars represent mean ± SEM of film density, displayed as percent control. Measurements were taken from different pups within each litter on P5, P15, and P30. Treatment effects on MBP mRNA levels in the cerebellum were restricted to P15, where 1 mg/kg A1254 induced a significant decrease in MBP mRNA levels (F3,23 = 3.291; P < 0.05). MBP mRNA was also reduced in the medulla, at this time, by 1 mg/kg A1254 (F3.23 = 4.926; P < 0.01). Interestingly, only the integrated density of the MBP signal was affected in the pons/medulla. On P5, MBP expression was not detected in the cerebellum.

Statistical analysis
Effects of treatment on body weight of the dams was evaluated using a one-way ANOVA with repeated measures; hormone levels and body weight of the pups were evaluated using a two-way ANOVA with main factors of treatment and age. One-way ANOVA was performed on the average film density and area over various brain areas, and the average number of grains per cell was determined for emulsion autoradiograms. All analyses were performed using the SuperAnova software package (Abacus Concepts, Inc., Berkeley, CA) on all data. Post hoc tests, where appropriate, were performed by Bonferroni’s t test, where the mean squared error term in the ANOVA table is used as the point-estimate of the pooled variance.

	Results

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Treatment with A1254 did not affect body weight (Fig. 1) or food consumption (data not shown) of the dams. In addition, treatment of the dams with A1254 did not alter the normal increase in body weight of the pups (Fig. 2; F_3,135 = 2.239; not significant). In contrast, A1254 administration to the dams significantly reduced the concentration of circulating total T₄ in pups in a dose-dependent manner [Fig. 3; F(A1254)_3,133 = 88.78, P << 0.001; F(age)_5,133 = 53.765, P << 0.001]. The severity of hypothyroxinemia induced by A1254 was age-dependent, because the concentration of total T₄ in serum was age-dependent. On day 15, total T₄ levels were maximal in control animals and were progressively reduced in animals exposed to increasing doses of A1254; 8 mg/kg A1254 reduced total T₄ to below the detection limit for the assay.

View larger version (24K): [in this window] [in a new window]   Figure 2. Effect of A1254 on body weight of pups. Dams were treated daily with different doses of A1254 as shown in the legend. No effects were observed at any age.

View larger version (29K): [in this window] [in a new window]   Figure 3. Circulating concentrations of total T4 in pups during A1254 exposure to the dams. Dams were treated daily with different doses of A1254 as shown in the legend. As expected, there was a postnatal rise in serum total T4, peaking on P15. However, total T4 was significantly reduced by A1254, in a dose-dependent manner, from P5 to P30. Pups derived from dams treated with 4 or 8 mg/kg/day did not exhibit a postnatal peak in total T4. Note: lower limit of detection was 10 µg/dl.

View larger version (55K): [in this window] [in a new window]   Figure 5. Effect of A1254 exposure on RC3/Neurogranin mRNA levels in the developing brain. Bars represent mean ± SEM film density, presented as percent control for the purposes of illustration. Regional measurements of density and area were taken from different pups within each litter on P5, P15, and P30. There were no treatment effects on RC3 mRNA levels on P5 or P30. However, on P15, RC3/Neurogranin mRNA levels, as reflected in film density, were significantly elevated in RSG (F3,25 = 3.027; P < 0.05), Pir (F3,24 = 3.129; P < 0.05), and DG (F3,26 = 3.436; P < 0.05). RC3/Neurogranin expression was not affected by treatment in any other brain region. *, P < 0.05, compared with 0-mg/kg group, using Bonferroni’s t test.

View larger version (97K): [in this window] [in a new window]   Figure 6. Effect of A1254 exposure on cellular levels of RC3/Neurogranin mRNA in retrosplenial cortex (RSG). A, Darkfield image of RSG from representative section of pup brain, on P15, derived from control dam (0 mg/kg A1254). B, Darkfield image of RSG from representative section of pup brain, on P15, derived from a dam treated with 8 mg/kg. Magnification = 200x. C, Quantitation of single cell level of RC3/Neurogranin mRNA in RSG. Bars represent the mean ± SEM grain number per cell, displayed as percent control. *, P < 0.05, compared with 0-mg/kg group, using Bonferroni’s t test.

	Discussion

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The purpose of this experiment was to test whether developmental exposure to PCBs produces antithyroid or thyromimetic effects on the developing brain. This question arises because PCB exposure is known to reduce circulating levels of thyroid hormone but to produce physiological or developmental effects that are not uniformly characteristic of antithyroid or thyromimetic actions (see first paragraph of text). Therefore, to directly address this question, we determined the effect of maternal PCB exposure on the expression of two genes known to be directly regulated by thyroid hormone during brain development. Our results confirmed that PCB exposure significantly reduces circulating levels of total T₄. This observation has been amply documented (14, 17, 18, 19), and others have shown that the same doses of A1254 also reduce free T₄, and total and free T₃ (18). However, despite severe reduction in circulating concentrations of thyroid hormone, our results demonstrate that on P15, when MBP and RC3/Neurogranin expression are most sensitive to thyroid hormone (43, 44), A1254 exposure elevated the expression of RC3/Neurogranin over that of controls. In addition, increasing doses of A1254 restored the expression of MBP in the developing brain despite the concomitant induction of severe hypothyroxinemia. The responses of MBP and RC3/Neurogranin expression to A1254 are clearly different from those predicted by the responses of these genes to chemical goitrogens such as propylthiouracil or methimazole (MMI). These goitrogens uniformly reduce the expression of MBP and RC3/Neurogranin in the developing brain (36, 34). Therefore, A1254 is not simply producing a hypothyroxinemic state that has predictable consequences based on studies with goitrogens.

Several aspects of the present data support the interpretation that maternal exposure to A1254 altered MBP and RC3/Neurogranin expression through the thyroid hormone signaling pathway. For example, thyroid hormone does not alter MBP expression in the cerebellum on P5 or P30, as shown by treatment with the goitrogen MMI (36). However, on P15, MMI treatment significantly reduces the expression of MBP in cerebellum. Thus, MBP expression exhibits the same temporal pattern of sensitivity to thyroid hormone and A1254. RC3/Neurogranin expression also is unaffected by MMI (45) or A1254 on P5. However, on P15, thyroid hormone regulates the expression of RC3/Neurogranin in the RSG and DG but not in CA1, CA2, CA3, or layers IV-II in the Oc2 (46). Considering that A1254 affected RC3/Neurogranin expression only in brain regions known to be sensitive to thyroid hormone, the effects of A1254 on RC3/Neurogranin expression are temporally and spatially similar to that of thyroid hormone.

The specific effects of A1254 on MBP and RC3/Neurogranin expression are different, but the general pattern is the same. For example, the relative abundance of MBP mRNA was significantly reduced by 1 mg/kg A1254, but higher doses of A1254 (4 and 8 mg/kg) restored levels to control values despite progressively more severe hypothyroxinemia. This general pattern was also observed in the response of RC3/Neurogranin expression. The 1 mg/kg dose did not affect RC3/Neurogranin expression, but higher doses (4 and 8 mg/kg) actually increased the abundance of RC3/Neurogranin mRNA. These results strongly suggest the possibility that two independent effects of A1254 exposure are operative in a dose-dependent manner. First, at lower doses, A1254 reduces circulating levels of T_4, and this effect produces consequences on the expression of some genes, such as MBP, and on developmental processes. At higher doses of exposure, specific PCB congeners may become concentrated in brain tissue to overcome or reverse the effects of the increasingly severe hypothyroxinemia, producing a thyromimetic effect.

The first effect of A1254 exposure is the obvious reduction in circulating T₄, and there is ample evidence supporting the concept that PCB-induced hypothyroxinemia directly affects brain development. For example, A1254 produces a hearing deficit in rats (18) similar to that produced by propylthiouracil treatment (47) that can be, at least partially, ameliorated with T₄ treatment (20). In addition, perinatal exposure to PCB reduces choline acetyltransferase activity in the cerebral cortex of rats, which was either partially or completely reversed by T₄ replacement, depending on brain area (21). Deficits in motor coordination, cognitive development, and muscular hypotonia in humans are some of the symptoms of congenital hypothyroidism that are correlated with background exposure to PCBs (12, 48). In Rotterdam (The Netherlands), PCB levels in women, chosen at random, were inversely related to serum total T₄ in their newborn children (49), and these PCB levels were also negatively correlated with birth size and early growth rate (50), as well as with various neurological measures (51). These observations lend credibility to the concern that PCB exposure can affect brain development by reducing circulating levels of thyroid hormone.

The second effect of developmental PCB exposure revealed by the present experiment is the thyromimetic effect that occurs at higher doses of PCB exposure. This effect was exemplified by the increased cellular expression of RC3/Neurogranin in the retrosplenial cortex. Considering that thyroid hormone increases the cellular expression of RC3/Neurogranin in the RSG by a transcriptional mechanism (46), it is possible that A1254 also is affecting both RC3/Neurogranin and MBP mRNA levels by a transcriptional mechanism. Therefore, it is possible that individual PCB congeners, or classes of congeners, can directly activate the TR, either as parent congeners or after hydroxylation or methylation. Several authors have speculated that specific PCB congeners are structurally similar enough to thyroid hormone to bind to the TR and perhaps influence thyroid hormone action (12, 13, 25, 28, 52). Individual PCB congeners can bind to several T₄-binding proteins, including transthyretin (53, 54), T₄-binding globulin (28), intracellular (55), and nuclear (52) T₄-binding sites. Cheek et al. (28) also have shown that specific PCB congeners can bind to the human TRß1. Although the affinity of TRß1 for individual PCB congeners (K_i = 32 µM) is low, the concentration of individual congeners in rat (56, 57) and human (58) brain tissue has been estimated to be as high as 50 µM (56). Though speculative, this hypothesis is consistent with the present results for both RC3/Neurogranin and MBP. In each case, the low dose of A1254 did not provide enough of these T₄-like PCB congeners to affect gene expression. However, at higher doses of A1254, thyroid hormone-like PCB congeners may have reached a concentration that restored MBP expression to normal, and increased RC3/Neurogranin expression, despite progressively more severe hypothyroxinemia.

The A1254 mixture used in the present experiment contains a large number of individual PCB congeners (59), which may account for these two effects on the thyroid axis. Some congeners are quite potent at reducing circulating levels of T₄, especially the non-ortho-substituted congeners that occupy a coplanar configuration such as 3,3',4,4',5-pentachlorobiphenyl (PCB 126) (60). However, these congeners do not become concentrated in brain tissue (57, 56, 61). In contrast, the ortho-substituted congeners that occupy a noncoplanar configuration, such as 2,2',4,4',5,5'-hexachlorobiphenyl (PCB 153), are not as potent at reducing circulating T₄ (60), but they do become concentrated in brain tissues of animals (56, 57, 61) and may bind to the TR (24). The observation that specific congeners, or classes of congeners, become selectively concentrated in tissues suggests that the dose and duration of exposure may interact such that a high dose/short exposure produces the same effects as low dose/long exposure.

It seems that metabolism of individual PCB congeners may be required for interactions with T₄-binding proteins. Brouwer and colleagues (19, 62) have shown that hydroxylated PCB congeners are present in fetal and neonatal rats born to dams gestationally exposed to PCBs. Moreover, hydroxylated congeners exhibit a higher affinity for binding to transthyretin than their parent congeners (14). Considering the large number of 209 possible congeners present in A1254 (56, 59) and the number of possible metabolic modifications, it will be challenging to perform the kinds of in vitro studies required to test directly whether individual PCB congeners can bind to the TR and transactivate gene expression.

An alternate (or additional) mechanism by which PCB exposure may produce a thyroid hormone-like effect on the developing brain is by enhancing thyroid hormone uptake into tissues and increasing the conversion of T₄ to T₃. Specifically, PCB-induced hypothyroxinemia may induce cellular uptake of T₄ or T₃ and increase the expression of deiodinases responsible for intracellular conversion of T₄ to T₃. Tissue uptake of T₃ or T₄ is elevated by reduced levels of T₄ (63, 64, 65), which also increases the expression of type II deiodinase in brain (66, 67). However, these processes are affected by hypothyroxinemia caused by goitrogens or PCBs, indicating that the differences in effects of these two treatments may not arise from the induction of compensatory mechanisms alone. Clearly, further work is required to understand the role of T₄ transport and deiodination in the regulation of thyroid hormone action during periods of hypothyroxinemia caused by different agents.

In conclusion, the present study clearly demonstrates that developmental exposure to a complex mixture of PCBs produces a severe reduction in circulating levels of thyroid hormone, but thyroid hormone-like effects on the expression of two separate thyroid hormone-responsive genes. These thyroid hormone-responsive genes are expressed in different cell types; RC3/Neurogranin mRNA is expressed in neurons (45), whereas MBP mRNA is expressed in oligodendrocytes (68). Thus, A1254 exerts a similar action on two separate genes expressed in very different types of cells. These data support the concept that the effect of A1254 on MBP and RC3/Neurogranin expression is mediated by the thyroid hormone signaling system. It is possible that individual PCB congeners within the A1254 mixture interact directly with the TR. The functional consequences of the effects we have documented are presently unclear, but these data are important because neurological development can be impaired by too little (69, 70) or too much (71) thyroid hormone; and the possibility that individual PCB congeners may interact directly with the TR suggests that PCBs may produce effects on neural development that are not consistent with effects on circulating levels of thyroid hormone.

	Acknowledgments

 
We thank Dr. Juan Bernal for his gift of the pPRC/CMV-RC3. We are also grateful to Dr. Richard Seegal for his advice concerning the method of Aroclor dosing, and to Dr. Kevin Crofton for many discussions about all aspects of this work. We also thank Jun Yang, Eric Iannacone, Alisa Croci, and Karen Terry for critically reviewing early versions of the manuscript. Finally, we are grateful to Christoffer Zoeller for his expert technical assistance with the extensive image analysis.

	Footnotes

 
¹ This work was supported by NIEHS Grant ES-08333 (to R.T.Z.).

Received August 12, 1999.

	References

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1. Tilson HA, Kodavanti PRS 1997 Neurochemical effects of polychlorinated biphenyls: an overview and identification of research needs. Neurotoxicology 13:727–744
2. Erickson MD 1986 Analytical Chemistry of PCBs. Butterworth, Boston
3. Tilson HA, Jacobson JL, Rogan WJ 1990 Polychlorinated biphenyls and the developing nervous system: Cross-species comparison. Neurotoxicology 13:139–148
4. Newsome HW, Davies D, Doucet J 1995 PCB and organochlorine pesticides in Canadian human milk - 1992. Chemosphere 30:2143–2153[Medline]
5. Dewailly E, Ryan JJ, Laliberte C, Bruneau S, Weber J-P, Gingras S, Carrier G 1994 Exposure of remote maritime populations to coplanar PCBs. Environ Health Perspect 102:205–209
6. Greizerstein HB, Stinson C, Mendola P, Buck GM, Kostyniak PJ, Vena JE 1999 Comparison of PCB congeners and pesticide levels between serum and milk from lactating women. Environ Res 80:280–286[Medline]
7. Gladen BC, Rogan WJ 1991 Effects of perinatal polychlorinated biphenyls and dichlorophenyl dichloroethene on later development. J Pediatr 119:58–63[CrossRef][Medline]
8. Jacobson JL, Jacobson SW 1996 Intellectual impairment in children exposed to polychlorinated biphenyls in utero. New Engl J Med 335:783–789[Abstract/Free Full Text]
9. Jacobson JL, Jacobson SW 1997 Evidence for PCBs as neurodevelopmental toxicants in humans. Neurotoxicology 18:415–424[Medline]
10. Jacobson JL, Jacobson SW, Humphrey HEB 1990 Effects of exposure to PCBs and related compounds on growth and activity in children. Neurotoxicol Teratol 12:319–326[CrossRef][Medline]
11. Jacobson WW, Fein GG, Jacobson JL, Schwartz PM, Dowler JK 1985 The effect of intrauterine PCB exposure on visual recognition memory. Child Dev 56:853–860[CrossRef][Medline]
12. Porterfield SP 1994 Vulnerability of the developing brain to thyroid abnormalities: environmental insults to the thyroid system. Environ Health Perspect [Suppl 2] 102:125–130[CrossRef]
13. Porterfield SP, Hendry LB 1998 Impact of PCBs on thyroid hormone directed brain development. Toxicol Ind Health 14:103–120[Medline]
14. Brouwer A, Morse DC, Lans MC, Schuur AG, Murk AJ, Klasson-Wehler E, Bergman A, Visser TJ 1998 Interactions of persistent environmental organohalides with the thyroid hormone system: mechanisms and possible consequences for animal and human health. Toxicol Ind Health 14:59–84[Medline]
15. Hauser P, McMillin JM, Bhatara VS 1998 Resistance to thyroid hormone: implications for neurodevelopmental research on the effects of thyroid hormone disruptors. Toxicol Ind Health 14:85–101[Medline]
16. Kolaja KL, Klaassen CD 1998 Dose-response examination of UDP-glucuronosyltransferase inducers and their ability to increase both TGF-B expression and thyroid follicular cell apoptosis. Toxicol Sci 46:31–37[Abstract/Free Full Text]
17. Barter RA, Klaassen CD 1992 UDP-glucoronosyltransferase inducers reduce thyroid hormone levels in rats by an extrathyroidal mechanism. Toxicol Appl Pharmacol 113:36–42[CrossRef][Medline]
18. Goldey ES, Kehn LS, Lau C, Rehnberg GL, Crofton KM 1995 Developmental exposure to polychlorinated biphenyls (Aroclor 1254) reduces circulating thyroid hormone concentrations and causes hearing deficits in rats. Toxicol Appl Pharmacol 135:77–88[CrossRef][Medline]
19. Morse DC, Wehler EK, Wesseling W, Koeman JH, Brouwer A 1996 Alterations in rat brain thyroid hormone status following pre- and postnatal exposure to polychlorinated biphenyls (Aroclor 1254). Toxicol Appl Pharmacol 136:269–279[CrossRef][Medline]
20. Goldey ES, Crofton KM 1998 Thyroxine replacement attenuates hypothyroxinemia, hearing loss, and motor deficits following developmental exposure to Aroclor 1254 in rats. Toxicol Sci 45:94–105[Abstract/Free Full Text]
21. Ku LMJD, Sharma-Stokkermans M, Meserve LA 1994 Thyroxine normalizes polychlorinated biphenyl (PCB) dose-related depression of choline acetyltransferase (ChAT) activity in hippocampus and basal forebrain of 15-day-old rats. Toxicology 94:19–30[CrossRef][Medline]
22. Cooke PS, Zhao Y-D, Hansen LG 1996 Neonatal polychlorinated biphenyl treatment increases adult testis size and sperm production in the rat. Toxicol Appl Pharmacol 136:112–117[CrossRef][Medline]
23. Cooke PS, Kirby JD, Porcelli J 1993 Increased testis growth and sperm production in adult rats following transient neonatal goitrogen treatment: optimization of the propylthiouracil dose and effects of methimazole. J Reprod Fertil 97:493–499[Abstract/Free Full Text]
24. McKinney JD 1989 Multifunctional receptor model for dioxin and related compound toxic action: possible thyroid hormone-responsive effector-linked site. Environ Health Perspect 82:323–336[Medline]
25. McKinney JD, Waller CL 1998 Molecular determinants of hormone mimicry: halogenated aromatic hydrocarbon environmental agents. J Toxicol Environ Health - Part B 1:27–58
26. Guo YL, Chen YC, Yu ML, Hsu CC 1994 Early development of Yu-Cheng children born seven to twelve years after the Taiwan PCB outbreak. Chemosphere 29:2395–2404[Medline]
27. Suresh PA, Sebastian S, George A, Radhakrishnan K 1999 Subclinical hyperthyroidism and hyperkinetic behavior in children. Pediatr Neurol 20:192–194[CrossRef][Medline]
28. Cheek AO, Kow K, Chen J, McLachlan JA 1999 Potential mechanisms of thyroid disruption in humans: interaction of organochlorine compounds with thyroid receptor, transthyretin, and thyroid-binding globulin. Environ Health Perspect 107:273–278[Medline]
29. Lazar MA 1993 Thyroid hormone receptors: multiple forms, multiple possibilities. Endocr Rev 14:184–193[Abstract/Free Full Text]
30. Lazar MA 1994 Thyroid hormone receptors: update 1994. Endocr Rev Monogr 3:280–283
31. Oppenheimer JH, Schwartz HL 1997 Molecular basis of thyroid hormone-dependent brain development. Endocr Rev 18:462–475[Abstract/Free Full Text]
32. Porterfield SP, Hendrich CE 1993 The role of thyroid hormones in prenatal neonatal neurological development-current perspectives. Endocr Rev 14:94–106[Abstract/Free Full Text]
33. Porterfield SP, Stein SA 1994 Thyroid hormones and neurological development: update 1994. Endocr Rev 3:357–363
34. Iniguez MA, DeLecea L, Guadano-Ferraz A, Morte B, Gerendasy D, Sutcliffe JG, Bernal J 1996 Cell-specific effects of thyroid hormone on RC3/neurogranin expression in rat brain. Endocrinology137:1032–1041
35. Farsetti A, Mitsuhashi T, Desvergne B, Robbins J, Nikodem VM 1991 Molecular basis of thyroid hormone regulation of myelin basic protein gene expression in rodent brain. J Biol Chem 266:23226–23232[Abstract/Free Full Text]
36. Ibarrola N, Rodriguez-Pena A 1997 Hypothyroidism coordinately and transiently affects myelin protein gene expression in most rat brain regions during postnatal development. Brain Res 752:285–293[CrossRef][Medline]
37. Marta CB, Adamo AM, Soto EF, Pasquini JM 1998 Sustained neonatal hyperthyroidism in the rat affects myelination in the central nervous system. J Neurosci Res 53:251–259[CrossRef][Medline]
38. Paxinos G, Watson C 1986 The rat brain in stereotaxic coordinates, ed 2. Academic Press, San Diego
39. Scott HC, Sun GY, Zoeller RT 1998 Prenatal ethanol exposure selectively reduces the mRNA encoding alpha-1 thyroid hormone receptor in fetal rat brain. Alcohol Clin Exp Res 22:2111–2117[Medline]
40. Zoeller RT, Butnariu OV, Fletcher DL, Riley EP 1994 Limited postnatal ethanol exposure permanently alters the expression of mRNAs encoding myelin basic protein and myelin-associated glycoprotein in cerebellum. Alcohol Clin Exp Res 18:909–916[CrossRef][Medline]
41. Dolan DH, Nichols MF, Fletcher D, Schadt JC, Zoeller RT 1992 Cold- and ethanol-induced hypothermia reduces cellular levels of mRNA-encoding thyrotropin-releasing hormone (TRH) in neurons of the preoptic area. Mol Cell Neurosci 3:425–432
42. Verity AN, Campagnoni AT 1988 Regional expression of myelin protein genes in the developing mouse brain: in situ hybridization studies. J Neurosci Res 21:238–248[CrossRef][Medline]
43. Schwartz HL 1983 Effect of thyroid hormone on growth and development. In: Oppenheimer JH, Samuels HH (eds) Molecular Basis of Thyroid Hormone Action. Academic Press, New York, pp 413–444
44. Schwartz HL, Ross ME, Oppenheimer JH 1997 Lack of effect of thyroid hormone on late fetal rat brain development. Endocrinology 138:3119–3124[Abstract/Free Full Text]
45. Iniguez M, Rodriguez-Pena A, Ibarrola N, Aguilera M, Escobar GMd, Bernal J 1993 Thyroid hormone regulation of RC3, a brain-specific gene encoding a protein kinase-C substrate. Endocrinology 133:467–473[Abstract/Free Full Text]
46. Guadano-Ferraz A, Escamez MJ, Morte B, Vargiu P, Bernal J 1997 Transcriptional induction of RC3/neurogranin by thyroid hormone: differential neuronal sensitivity is not correlated with thyroid hormone receptor distribution in the brain. Mol Brain Res 49:37–44[Medline]
47. Goldey ES, Kehn LS, Rehnberg GL, Crofton KM 1995 Effects of developmental hypothyroidism on auditory and motor function in the rat. Toxicol Appl Pharmacol 135:67–76[CrossRef][Medline]
48. Dussault JH, Walker P 1983 Congenital hypothyroidism. Dekker, New York
49. Koopman-Esseboom C, Morse DC, Weisglas-Kuperus N, Lutkeschiphost IJ, Paauw CBvD, Tuinstra LGMT, Brouwer A, Sauer PJJ 1994 Effects of dioxins and polychlorinated biphenyls on thyroid hormone status of pregnant women and their infants. Pediatr Res 36:468–473[Medline]
50. Patandin S, Koopman-Esseboom C, Ridder MAD, Weisglas-Kuperus N, Sauer PJ 1998 Effects of environmental exposure to polychlorinated biphenyls and dioxins on birth size and growth in Dutch children. Pediatr Res
51. Koopman-Esseboom C, Huisman M, Touwen BC, Boersma ER, Brouwer A, Sauer PJ, Weisglas-Kuperus N 1997 Newborn infants diagnosed as neurologically abnormal with relation to PCB and dioxin exposure and their thyroid-hormone status. Dev Med Child Neurol 39:785[Medline]
52. McKinney J, Fannin R, Jordan S, Chae K, Rickenbacher U, Pedersen L 1987 Polychlorinated biphenyls and related compound interactions with specific binding sites for thyroxine in rat liver nuclear extracts. J Med Chem 30:79–86[CrossRef][Medline]
53. Brouwer A, Berg KJVD 1986 Binding of a metabolite of 3,4,3',4'-tetrachlorobiphenyl to transthyretin reduces serum vitamin A by inhibiting the formation of the protein complex carrying both retinol and thyroxin. Toxicol Appl Pharmacol 85:301–312[CrossRef][Medline]
54. Darnerud PO, Morse D, Klasson-Wehler E, Brouwer A 1996 Binding of a 3,3',4,4'-tetrachlorobiphenyl (CB-77) metabolite to fetal transthyretin and effects on fetal thyroid hormone levels in mice. Toxicology 106:105–114[CrossRef][Medline]
55. Brundl A, Buff K 1993 Partial purification and characterization of a rat liver polychlorinated biphenyl (PCB) binding protein. Biochem Pharmacol 45:885–891[CrossRef][Medline]
56. Kodavanti PRS, Ward TR, Derr-Yellin EC, Mundy WR, Casey AC, Bush B, Tilson HA 1998 Congener-specific distribution of polychlorinated biphenyls in brain regions, blood, liver, and fat of adult rats following repeated exposure to Aroclor 1254. Toxicol Appl Pharmacol 153:199–210[CrossRef][Medline]
57. Shain W, Overmann SR, Wilson LR, Kostas J, Bush B 1986 A congener analysis of polychlorinated biphenyls accumulating in rat pups after perinatal exposure. Arch Environ Contam Toxicol 15:687–707[CrossRef][Medline]
58. Dewailly E, Hansen JC, Pedersen HS, Mulvad G, Ayotte P, Weber JP, Lebel G 1995 Concentration of PCBs in various tissues from autopsies in Greenland. Organohalogen Compd 26:175–180
59. Frame GM, Cochran JW, Bowadt SS 1996 Complete PCB congener distributions for 17 Aroclor mixtures determined by 3 HRGC systems optimized for comprehensive, quantitative, congener-specific analysis. J High Resol Chromatogr 19:657–668[CrossRef]
60. Seo B-W, Li M-H, Hansen LG, Moore RW, Peterson RE, Schantz SL 1995 Effects of gestational and lactational exposure to coplanar polychlorinated biphenyl (PCB) congeners or 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) on thyroid hormone concentrations in weanling rats. Toxicol Lett 78:253–262[CrossRef][Medline]
61. Morse DC, Groen D, Veerman M, Amerongen CJV, Koeter HBWM, Prooije AESV, Visser TJ, Koeman JH, Brouwer A 1993 Interference of polychlorinated biphenyls in hepatic and brain thyroid hormone metabolism in fetal and neonatal rats. Toxicol Appl Pharmacol 122:27–33[CrossRef][Medline]
62. Morse DC, Klasson-Wehler E, Pas MVD, Bie ATHJD, Bladeren PJV, Brouwer A 1995 Metabolism and biochemical effects of 3,3',4,4'-tetrachlorobiphenyl in pregnant and fetal rats. Chem Biol Interact 95:41–56[CrossRef][Medline]
63. Everts ME, Visser TJ, Moerings EPCM, Docter R, Toor Hv, Tempelaars AMP, Jong MD, Krenning EP, Hennemann G 1994 Uptake of triiodothyroacetic acid and its effect on thyrotropin secretion in cultured anterior pituitary cells. Endocrinology135:2700–2707
64. Friesema ECH, Docter R, Moerings EPCM, Stieger B, Hagenbuch B, Meier PJ, Krenning EP, Hennemann G, Visser TJ 1999 Identification of thyroid hormone transporters. Biochem Biophys Res Commun 254:497–501[CrossRef][Medline]
65. Moreau X, Lejeune PJ, Jeanningros R 1999 Kinetics of red blood cell T3 uptake in hypothyroidism with or without hormonal replacement, in the rat. J Endocrinol Invest 22:257–261[Medline]
66. Burmeister LA, Pachucki J, Germain DLS 1997 Thyroid hormones inhibit type 2 iodothyronine deiodinase in the rat cerebral cortex by both pre- and posttranslational mechanisms. Endocrinology138:5231–5237
67. Germain DLS, Galton VA 1997 The deiodinase family of selenoproteins. Thyroid 7:655–668[Medline]
68. Shiota C, Miura M, Mikoshiba K 1989 Developmental profile and differential localization of mRNAs of myelin proteins (MBP and PLP) in oligodendrocytes in the brain and in culture. Dev Brain Res 45:83–94[Medline]
69. LaFranchi S 1999 Thyroid function in the preterm infant. Thyroid 9:71–78[Medline]
70. Vliet GV 1999 Neonatal hypothyroidism: treatment and outcome. Thyroid 9:79–84[Medline]
71. Lauder JM 1977 The effects of early hypo- and hyperthyroidism on the development of rat cerebellar cortex. III. Kinetics of cell proliferation in the external granular layer. Brain Res 126:31–51[CrossRef][Medline]

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