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COMPARATIVE AND EVOLUTIONARY PHYSIOLOGY

3,5-Diiodothyronine in vivo maintains euthyroidal expression of type 2 iodothyronine deiodinase, growth hormone, and thyroid hormone receptor 1 in the killifish

¹Instituto de Neurobiología, Departamento de Neurobiología Celular y Molecular, Universidad Nacional Autónoma de México, Querétaro, Mexico; and ²The Whitney Laboratory, University of Florida, St. Augustine, Florida

Submitted 12 February 2007 ; accepted in final form 16 May 2007

	ABSTRACT

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Until recently, 3,5-diiodothyronine (3,5-T₂) has been considered an inactive by-product of triiodothyronine (T₃) deiodination. However, studies from several laboratories have shown that 3,5-T₂ has specific, nongenomic effects on mitochondrial oxidative capacity and respiration rate that are distinct from those due to T₃. Nevertheless, little is known about the putative genomic effects of 3,5-T₂. We have previously shown that hyperthyroidism induced by supraphysiological doses of 3,5-T₂ inhibits hepatic iodothyronine deiodinase type 2 (D2) activity and lowers mRNA levels in the killifish in the same manner as T₃ and T₄, suggesting a pretranslational effect of 3,5-T₂ (Garcia-G C, Jeziorski MC, Valverde-R C, Orozco A. Gen Comp Endocrinol 135: 201–209, 2004). The question remains as to whether 3,5-T₂ would have effects under conditions similar to those that are physiological for T₃. To this end, intact killifish were rendered hypothyroid by administering methimazole. Groups of hypothyroid animals simultaneously received 30 nM of either T₃, reverse T₃, or 3,5-T₂. Under these conditions, we expected that, if it were bioactive, 3,5-T₂ would mimic T₃ and thus reverse the compensatory upregulation of D2 and tyroid receptor 1 and downregulation of growth hormone that characterize hypothyroidism. Our results demonstrate that 3,5-T₂ is indeed bioactive, reversing both hepatic D2 and growth hormone responses during a hypothyroidal state. Furthermore, we observed that 3,5-T₂ and T₃ recruit two distinct populations of transcription factors to typical palindromic and DR4 thyroid hormone response elements. Taken together, these results add further evidence to support the notion that 3,5-T₂ is a bioactive iodothyronine.

deiodinase type 2; thyroid hormone receptor 1; thyroid hormone response element; killifish

One prevailing question is how 3,5-T₂ is formed in the target cell. Although conversion of T₃ to 3,5-T₂ has not been demonstrated in mammals (21) or in teleosts in vitro (A. Orozco, unpublished observations; Ref. 31), indirect but robust evidence indicates that 3,5-T₂ is indeed formed from T₃ in vivo through deiodination (23). It is not yet known which deiodinase catalyzes the conversion of T₃ to 3,5-T₂, either in vivo or in vitro, but a likely candidate is iodothyronine deiodinase type 2 (D2). D2 catalyzes the removal of outer-ring iodine from T₄ to generate the bioactive hormone T₃ and thus determines T₃ availability at the cellular level. Conversion of T₃ to 3,5-T₂ would require similar outer-ring deiodination.

Our laboratory has previously studied whether 3,5-T₂ has a regulatory effect upon D2 in Fundulus heteroclitus (killifish). In this species, hepatic D2 expression is very abundant, among the highest in vertebrates so far examined (26, 28). The D2 gene is tightly downregulated by bioactive TH (for review: Refs. 4, 5). We have found that hyperthyroidism induced by a short-term immersion (up to 24 h) of killifish in seawater (SW) supplemented with 3,5-T₂ significantly decreased both mRNA expression and hepatic activity of D2, mimicking the effects of T₄ or T₃ (10). Because these effects were obtained with supraphysiological doses of the three iodothyronines, in this work, we asked whether 3,5-T₂, when administered in doses similar to those known to be physiological for T₃, could reestablish the euthyroidal activity and hepatic expression of D2 in hypothyroid killifish. We also examined the effects of 3,5-T₂ upon the hepatic expression of GH, which is upregulated in the pituitary by hyperthyroid status (1, 11, 32). Finally, as a first approach to study the action mechanism of 3,5-T₂ in the killifish, we analyzed the hepatic expression of the TR1 and the TH response element (TRE)-transcription factor complexes formed in response to treatment with 3,5-T₂ or T₃.

	MATERIALS AND METHODS

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Animals. SW-adapted male Fundulus heteroclitus, ranging from 4 to 6 g, were collected from the estuarine creeks of the Matanzas River (St. Augustine, FL). After capture, fish were kept in tanks with running SW piped directly from the ocean at a temperature of 28°C. Animals were deparasitized after capture, fed ad libitum 24 h later (Silver Cup, Nelson and Sons), and maintained on a light-dark cycle of 14:10 h. Collection of the tissues for the different experiments was performed as follows: fish were decapitated, and the liver was rapidly removed. Each liver was divided in half to determine both deiodinase activity and mRNA levels. Segments used to measure deiodinase activity were homogenized in 10 volumes of ice-cold homogenization buffer [10 mM HEPES (Sigma), 0.25 M sucrose (Sigma), 10 mM EDTA (Sigma), pH 7]. Aliquots were quick-frozen in liquid nitrogen and stored at –70°C until assayed. To quantify mRNA, segments were pooled (n = 2–3/pool) for RNA extraction. All animal experimentation was conducted in accord with accepted standards of humane animal care, and procedures regarding handling and euthanasia of animals were reviewed and approved by the Animal Welfare Committee of our Institute.

Experimental design. Our laboratory (10) and others (9, 25) have established that the administration of hydrophobic drugs by immersion provides an efficient, noninvasive, and minimally stressful means of chronically administering these compounds in aquatic vertebrates. We used this method to deliver all treatments in the present work. The dose-response curves for T₃ and 3,5-T₂ were performed by supplementing the environmental SW with 10, 30, 100, and 300 nM of either iodothyronine (Sigma) for 24 h (vehicle: 0.01 N NaOH) or vehicle only. For time-response curves, a final concentration of 100 nM of either T₃ or 3,5-T₂ was administered by immersion for 3, 6, 12, 18, and 24 h (n = 6). Fish were killed after the treatment, the liver was dissected, and D2 activity was determined.

Since the aim of the present study was to analyze the effects of 3,5-T₂ and to compare them to those exerted by physiological doses of T₃, we treated the different experimental groups with methimazole (MMI; Sigma), an inhibitor of TH synthesis, at a final concentration of 4.5 mM, with or without simultaneous addition of T₃, reverse T₃ (rT₃), or 3,5-T₂ (Sigma) at a final concentration of 30 nM (vehicle: 0.01 N NaOH). Based on the dose-response curve results from euthyroid animals (see above), we simultaneously added different doses (10, 30, and 100 nM) of either T₃ or 3,5-T₂ to the MMI-treated fish. We found that 30 nM of exogenous T₃ merely restored intrahepatic concentrations of this hormone, whereas higher doses elevated intrahepatic T₃ above control levels (data not shown). Based on these results, we defined 30 nM as the effective immersion dose at which intrahepatic euthyroidism is attained. For each experiment, fish (n = 18/experimental group) were placed into tanks with running SW and constant aeration. After 12 h of acclimation, the water flow was shut off, and the water volume of each tank was adjusted to 6 liters. Control groups were handled in the same manner as the experimental groups. Fish were killed after 5 days of treatment. Six livers from control, MMI, MMI + T₃, and MMI + 3,5-T₂ groups were individually prepared for iodothyronine extraction and measurement of T₃ (RIA). All of the experimental treatments were performed at least twice in independent groups.

RIA of iodothyronines. To determine intrahepatic T₃ levels, individual livers were homogenized, and iodothyronines were extracted as previously described (10). Livers (average wet weight 100 ± 7 mg) were homogenized in 10 volumes of methanol-ammonium hydroxide (99:1) solution. The homogenates were centrifuged for 10 min at 700 g. The supernatants were collected, evaporated in a speed vacuum, and suspended 1:5 (initial weight/volume) in assay buffer Tris·HCl (0.05 M; pH 8.6). Hepatic content of T₃ was measured by RIA as previously described (27). The inter- and intra-assay coefficients of variation were 9.5 and 6.6%, respectively. The incubation mixture contained assay buffer and a working dilution (1:8,000) of anti-T₃ serum (Sigma), standard (standard curve, 7.8–1,000 pg/dl), the radioactive solution (10 pg/100 µl of the labeled T₃ plus 10 mg/10 ml of 8-anilino-1-naphthalene sulfonic acid, Sigma), and 50 µl of the experimental sample. Free and antibody-bound radioactive T₃ were separated using 0.5% activated charcoal/dextran suspension (Sigma).

Deiodination assay. Enzyme activities were measured in duplicate as previously described (26). The total volume of the reaction mixture was 100 µl and contained 1 nM ¹²⁵I-T₄ (sp. act. 1,200 µCi/µg; New England Nuclear) plus 25 mM DTT (Calbiochem) and liver homogenate at a protein concentration of 100 µg. Assays were incubated for 1 h at 37°C. The released, acid-soluble ¹²⁵I was isolated by chromatography on Dowex 50W-X2 columns (BioRad). Specific activity was calculated as previously described (29) and expressed as femtomoles of ¹²⁵iodide per hour per milligram. Protein content was measured by the Bradford method (BioRad).

Measurement of D2 mRNA. RNA was isolated from treated or control livers using TRIzol (Invitrogen), and cDNA was reverse transcribed (Superscript, Invitrogen) from 10 µg RNA using a gene-specific primer (5' TTC AGA GCT CAT CTA CTA TCG T 3'). The concentration of D2 mRNA was measured in duplicate by competitive PCR, as previously described (10). The standard curve ranged from 10⁴ to 10⁹ molecules/µl. Oligonucleotides used (sense: 5' CAA ACA GGT GAA ACT TGG CT 3' and antisense: 5' TCG TCG ATG TAG ACC AGC 3') amplified a product of 270 bp (40 s at 94°, 40 s at 65°, 30 s at 72° for 35 cycles). Identical PCRs from the RNA samples before the reverse transcription reaction yielded no detectable products, indicating that the RNA was not contaminated with genomic DNA. Results are expressed as molecules per microgram of total mRNA used in the reverse transcription.

Measurement of GH mRNA. Total RNA was extracted from male killifish brains (including the pituitary) with TRIzol and used as a template for reverse transcription of cDNA using an oligo-dT-polylinker primer. A degenerate primer (5' TGY TTY AAR AAR GAY ATG CAY AAR 3') that contained a sequence conserved in 35 teleost GH cDNAs reported in GeneBank (CFKKDMHKV) was used with an oligo-dT-polylinker primer to generate a first fragment, which included the stop codon of the killifish GH cDNA. The 5' end of the cDNA was amplified using rapid amplification of cDNA ends. A cDNA was reversed transcribed using a specific antisense primer. This cDNA was purified and tailed with dCTP using terminal transferase, and an oligo-dG-polylinker primer was used in combination with exact primers in a series of nested amplifications to generate the 5' end. The open reading frame of the GH cDNA clone obtained had 64% identity to the other 35 teleost GH genes reported in GeneBank. This sequence was inserted into a vector (pGEM-T, Promega) and used to construct a standard curve. Primers specific for this sequence were designed for real-time PCR (see below).

Reverse transcription (Superscript) from 10 µg of total hepatic RNA was performed using an oligo(dT) primer (final volume of 20 µl). Real-time PCR was carried out in duplicate using -actin as internal standard in reactions that contained 1 µl aliquots of the reverse transcription reaction described above, corresponding to 0.5 µg total RNA, 7.5 µl of TAQurate GREEN Real-Time PCR MasterMix (EPICENTRE), and 500 nM forward and reverse primers in a final volume of 15 µl. A 233-bp fragment from killifish -actin (accession number: CN985078) was cloned with oligonucleotides 5' GCG ACA TCA AGG AGA AGC T 3' (sense) and 5' CGA CGT CGC ACT TCA TGAT 3' (antisense) and used to construct a standard curve (10³–10⁸ molecules/µl). This same combination of primers was used to measure -actin in the experimental samples (3 s at 94°C, 8 s at 61°C, 9 s at 72°C for 45 cycles). For GH cDNA, the standard curve ranged from 10¹ to 10⁶ molecules/µl. The oligonucleotides used were 5' GAT CTC CCC CAA ACT GTC A 3' (sense) and 5' GAC TCA TCA GCT TCC AGA CT 3' (antisense). These primers generated a product of 146 bp (3 s at 94°C, 5 s at 55°C, 7 s at 72°C for 45 cycles). Detection and data analyses were carried out on a Light Cycler instrument, according to the manufacturer's instructions (Roche Molecular Biochemicals, Mannheim, Germany). Fluorescence analysis was performed after each cycle, and the PCR products generated were analyzed with a melting curve to verify the specificity of the amplified products. The mRNA concentration (molecules/µl), obtained by comparison with the standard curve, was normalized to the concentration of -actin in each experimental sample. As indicated for D2 expression, identical PCRs from the RNA samples before the reverse transcription reaction yielded no detectable products. Results are expressed as molecules/µg of total mRNA used in the reverse transcription.

Measurement of Na-K-ATPase ₁-mRNA. Reverse transcription and real-time PCRs were conducted as described above. Based on the reported sequence for the killifish ₁-subunit of the Na-K-ATPase cDNA (accession number AY057072; Ref. 30), a fragment containing the open-reading frame was amplified (sense: 5' GGG AAG TTT TGA AAA AGA AAA TTG 3' and antisense: 5' GCC TTG CAA CAC GAT GGT G 3' primers), subcloned (pGEM-T, Promega), and used to construct a standard curve (10³–10⁸ molecules/µl). A product of 256 bp was amplified with sense (5' GGA ACT GCC AGA GGA ATT G 3') and antisense (5' GGA GAC CTT CTG GCA CAT TA 3') primers (3 s at 94°C, 6 s at 64°C, 10 s at 72°C for 45 cycles). Identical PCRs from the RNA samples before the reverse transcription reaction yielded no detectable products.

Measurement of TR1 mRNA. Total RNA was extracted from male killifish livers (TRIzol, Invitrogen) and used as a template for reverse transcription of cDNA using an oligo-dT-polylinker primer. A pair of degenerate primers (sense: 5' TGA GTG CAG IGG GGG TGA AG 3' and antisense: 5' GAC ATG ATC TCC ATR CAR CA 3') that contained highly conserved TR1 cDNA sequences previously reported in several teleosts (22) was used to clone a 230-bp fragment that had 84% identity to the other teleost TR1 genes reported. This fragment was inserted into a vector (pGEM-T, Promega) and used to construct a standard curve (10³–10⁸ molecules/µl). Primers specific for this sequence were designed for real-time PCR.

Reverse transcription and real-time PCRs were conducted as described above. A product of 180 bp was amplified with sense (5' TGA GTG CAG GGG GGG GTG AAG 3') and antisense (5' GCA GCT CAC AGA ACA TGG GC 3') primers (3 s at 94°C, 5 s at 65°C, 8 s at 72°C for 45 cycles). Identical PCRs from the RNA samples before the reverse transcription reaction yielded no detectable products.

Nuclear extracts. Nuclear proteins were obtained as previously described (20). In brief, untreated fish (control) or fish treated with MMI only or MMI plus either T₃ or 3,5-T₂ (30 nM) for 5 days were killed, and the livers were resuspended 1:10 (wt/vol) in a hypotonic buffer (10 mM HEPES, pH 7.9, 10 mM KCl, 1 mM EDTA, 5 mM DTT). After mechanical disruption, the tissues were incubated at 4°C for 30 min, and the supernatants were collected. The quality of the nuclei was evaluated with a Trypan blue stain (1:1). Nuclei were centrifuged at 800 g for 10 min. The pellet was resuspended in hypertonic buffer (50 mM Tris·HCl, pH 7.5, 400 mM KCl, 400 mM NaCl, 10% glycerol, 1 mM EDTA, 5 mM DTT, 0.5 mM PMSF) and agitated at 4°C for 30 min. After centrifugation at 16,000 g for 25 min, the supernatant was diluted in an equal volume of dilution buffer (20 mM HEPES, pH 7.9, 50 mM KCl, 20% glycerol, 0.2 mM EDTA, 0.5 mM PMSF, 1 mM DTT) for protein quantification by the Bradford method.

Electrophoretic mobility shift assay. Nuclear protein extracts (10 µg) of liver were incubated with ³²P-labeled TRE oligonucleotides for either DR4 (5' AGC TTC AGG_TCA_CAG GAG_GTC_AGA GAG 3') or palindromic sites (5' AAG ATT CAG_GTC_ATG_ACC_TGA GGA GA 3') (Santa Cruz Biotechnology, Santa Cruz, CA). The binding reactions were incubated on ice for 40 min in a buffer containing 20 mM HEPES, 50 mM KCl, 20% glycerol, 0.2 mM EDTA, 0.5 mM PMSF, 1 mM DTT, 1 µg/µl BSA, and 1 µg/µl poly(dI-dC) (Pharmacia). The reaction mixture was loaded onto a 5% non-denaturating polyacrylamide gel and resolved at 120 V over the course of 4 h. The gel was dried, and the DNA-protein complexes were visualized by exposure in a Storage Phosphor Screen (Molecular Dynamics, Sunnyvale, CA). The screens were read in a Storm Phosphorimager and analyzed with the ImageQuant software (Molecular Dynamics).

Statistical analysis. Results obtained in all experiments were analyzed using a one-way analysis of variance coupled with Bonferroni's multiple-comparison test (control vs. treatments). Differences were considered statistically significant at P values of 0.01.

	RESULTS AND DISCUSSION

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In the present study, we investigated the genomic or extra-mitochondrial thyromimetic effects of 3,5-T₂ at concentrations similar to those physiological for T₃. Previous data from our laboratory had shown that, as in other vertebrates (4, 5, 16), hepatic D2 activity in the killifish is highly sensitive to thyroidal status (10). Thus, and due to the difficulties of measuring 3,5-T₂, we initially established the concentration range of its regulatory action on D2 by comparing the effects of 3,5-T₂ to those of T₃ in intact (euthyroid) killifish. Dose- and time-dependent activities for both hormones are shown in Fig. 1. The well-known downregulatory effect of T₃ was indistinguishable from that exerted by 3,5-T₂, both showing a dose-dependent inhibition, which attained a plateau at an immersion dose of 100 nM and as early as 3 h postimmersion. These findings suggested that both hormones had comparable potencies at equivalent doses. To analyze 3,5-T₂ effects in more detail, we used a model of hypothyroidism where the administration of active TH was anticipated to maintain euthyroidal expression of the various thyroid-dependent genes. As shown in Fig. 2, intrahepatic T₃ levels were significantly decreased by the administration of MMI alone. As expected, this decrease was reversed by coadministration of T₃ but not 3,5-T₂. In fact, levels of endogenous intrahepatic T₃ in fish treated with 3,5-T₂ combined with MMI were no higher than in fish treated with MMI alone. This finding is very important, because it shows that the livers of animals treated with MMI coadministered with 3,5-T₂ are indeed T₃ deficient.

View larger version (20K): [in this window] [in a new window]   Fig. 1. Dose- (top) and time-response curves (bottom) of hepatic iodothyronine deiodinase type 2 (D2) activity after treatment with triiodothyronine (T3) or with 3,5-diiodothyronine (3,5-T2). Environmental seawater was supplemented with 10, 30, 100, and 300 nM of either iodothyronine for 24 h. For time-response curves, a final concentration of 100 nM of either T3 or 3,5-T2 was administered by immersion for 3, 6, 12, 18, and 24 h. Values are means ± SE (n = 6). Significance is indicated (*P < 0.01; **P < 0.001).

View larger version (11K): [in this window] [in a new window]   Fig. 2. Intrahepatic concentrations of T3 in killifish treated for 5 days with 4.5 mM methimazole (MMI), either alone or with 30 nM T3 or 30 mM 3,5-T2. Values are means ± SE (n = 6). Significance is indicated (*P < 0.01; **P < 0.001).

View larger version (15K): [in this window] [in a new window]   Fig. 3. Effect of a 5-day treatment with 4.5 mM MMI either alone or with 30 nM T3, reverse T3 (rT3), or 3,5-T2 on killifish D2 mRNA expression (competitive PCR; pooled livers, n = 4 pools/experimental group) (A) and hepatic D2 activity (n = 12–14) (B). Values are means ± SE. Significance is indicated (*P < 0.01; **P < 0.001).

Treatment with the inactive iodothyronine rT₃ had no effect on MMI-induced increases in D2. This result differs from mammalian D2 regulation, where rT₃ increases D2 degradation in the cerebral cortex (for review see Refs. 4, 5). This is the first study of the rT₃ effect on the regulation of a teleostean D2. Although we cannot offer an explanation for the lack of effect of rT₃ upon D2 regulation, this result adds to the unique aspects of iodothyronine deiodinases in teleosts.

As another test of our hypothesis, we analyzed the expression of GH, a gene that is classically upregulated by TH in the pituitary (11, 15). Here we demonstrated GH expression in the liver of killifish, as reported earlier in trout (33). This finding allowed the same end tissue to be analyzed throughout the study. As expected (14) and shown in Fig. 4, hepatic GH mRNA levels were reduced by threefold in hypothyroid animals. The effects of MMI on GH expression were reversed by 30 nM T₃ but not by rT₃, similar to the effects seen on D2 expression. When 3,5-T₂ was coadministered with MMI, hepatic GH mRNA levels were similar to those in untreated or MMI+T₃-treated fish. These data add further support for the hypothesis that 3,5-T₂, like T₃, can reverse the impaired expression of hepatic GH associated with the hypothyroidal state.

View larger version (13K): [in this window] [in a new window]   Fig. 4. Effect of a 5-day treatment with 4.5 mM MMI either alone or with 30 nM T3, rT3, or 3,5-T2 on killifish hepatic growth hormone mRNA expression (real-time PCR; pooled livers, n = 4 pools/experimental group). Values are means ± SE. Significance is indicated (*P < 0.01).

View larger version (13K): [in this window] [in a new window]   Fig. 5. Effect of a 5-day treatment with 4.5 mM MMI either alone or with 30 nM T3, rT3, or 3,5-T2 on killifish hepatic Na-K-ATPase 1-mRNA expression (real-time PCR; pooled livers, n = 4 pools/experimental group). Values are means ± SE.

View larger version (48K): [in this window] [in a new window]   Fig. 6. A: representative EMSAs of nuclear extracts from killifish livers treated with MMI (4.5 mM) and replacement doses of 30 nM T3 or 3,5-T2. The ideal DR4 or palindromic thyroid hormone response element (TRE) oligonucleotides were 32P labeled. Densitometric analysis show the upper (B) and lower (C) complexes formed (n = 3 different assays from 3 independent experiments). Values are means ± SE. Significance is indicated (**P < 0.001).

View larger version (13K): [in this window] [in a new window]   Fig. 7. Effect of a 5-day treatment with 4.5 mM MMI either alone or with 30 nM T3, rT3, or 3,5-T2 on killifish hepatic thyroid receptor 1 mRNA expression measured by real-time PCR (pooled livers, n = 4 pools/experimental group). Values are means ± SE. Significance is indicated (*P < 0.01).

	GRANTS

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This work was partially supported by Programa de Apoyo a Proyectos de Investigación e Innovación Tecnológica (PAPIIT) Grants PAPIIT IN222405 and PAPIIT IN202807.

	ACKNOWLEDGMENTS

 
We gratefully acknowledge Patricia Villalobos and Anaid Antaramian for technical assistance. We would like to express our gratitude to Dr. Dorothy Pless for critically reviewing the manuscript.

	FOOTNOTES

 

Address for reprint requests and other correspondence: A. Orozco, Instituto de Neurobiología, UNAM, Campus UNAM-UAQ, Juriquilla, Querétaro, Qro 76230, México (e-mail: aureao{at}servidor.unam.mx)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

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