The type 2 iodothyronine deiodinase is essential for adaptive thermogenesis in brown adipose tissue.

Type 2 iodothyronine deiodinase (D2) is a selenoenzyme, the product of the recently cloned cAMP-dependent Dio2 gene, which increases 10- to 50-fold during cold stress only in brown adipose tissue (BAT). Here we report that despite a normal plasma 3,5,3'-triiodothyronine (T3) concentration, cold-exposed mice with targeted disruption of the Dio2 gene (Dio2(-/-)) become hypothermic due to impaired BAT thermogenesis and survive by compensatory shivering with consequent acute weight loss. This occurs despite normal basal mitochondrial uncoupling protein 1 (UCP1) concentration. In Dio2(-/-) brown adipocytes, the acute norepinephrine-, CL316,243-, or forskolin-induced increases in lipolysis, UCP1 mRNA, and O(2) consumption are all reduced due to impaired cAMP generation. These hypothyroid-like abnormalities are completely reversed by a single injection of T3 14 hours earlier. Recent studies suggest that UCP1 is primarily dependent on thyroid hormone receptor beta (TR beta) while the normal sympathetic response of brown adipocytes requires TR alpha. Intracellularly generated T3 may be required to saturate the TR alpha, which has an approximately fourfold lower T3-binding affinity than does TR beta. Thus, D2 is an essential component in the thyroid-sympathetic synergism required for thermal homeostasis in small mammals.

Thyroid hormone--sympathetic interaction and adaptive thermogenesis are thyroid hormone receptor isoform--specific.

In newborns and small mammals, cold-induced adaptive (or nonshivering) thermogenesis is produced primarily in brown adipose tissue (BAT). Heat production is stimulated by the sympathetic nervous system, but it has an absolute requirement for thyroid hormone. We used the thyroid hormone receptor-beta--selective (TR-beta--selective) ligand, GC-1, to determine by a pharmacological approach whether adaptive thermogenesis was TR isoform--specific. Hypothyroid mice were treated for 10 days with varying doses of T3 or GC-1. The level of uncoupling protein 1 (UCP1), the key thermogenic protein in BAT, was restored by either T3 or GC-1 treatment. However, whereas interscapular BAT in T3-treated mice showed a 3.0 degrees C elevation upon infusion of norepinephrine, indicating normal thermogenesis, the temperature did not increase (<0.5 degrees C) in GC-1--treated mice. When exposed to cold (4 degrees C), GC-1--treated mice also failed to maintain core body temperature and had reduced stimulation of BAT UCP1 mRNA, indicating impaired adrenergic responsiveness. Brown adipocytes isolated from hypothyroid mice replaced with T3, but not from those replaced with GC-1, had normal cAMP production in response to adrenergic stimulation in vitro. We conclude that two distinct thyroid-dependent pathways, stimulation of UCP1 and augmentation of adrenergic responsiveness, are mediated by different TR isoforms in the same tissue.

Type 2 iodothyronin deiodinase transgene expression in the mouse heart causes cardiac-specific thyrotoxicosis.

Type 2 iodothyronine deiodinase (D(2)) catalyzes intracellular 3, 5, 3' triiodothyronine (T(3)) production from thyroxine (T(4)), and its messenger RNA mRNA is highly expressed in human, but not rodent, myocardium. The goal of this study was to identify the effects of D(2) expression in the mouse myocardium on cardiac function and gene expression. We prepared transgenic (TG) mice in which human D(2) expression was driven by the alpha-MHC promoter. Despite high myocardial D(2) activity, myocardial T(3) was, at most, minimally increased in TG myocardium. Although, plasma T(3) and T(4), growth rate as well as the heart weight was not affected by TG expression, there was a significant increase in heart rate of the isolated perfused hearts, from 284 +/-12 to 350 +/- 7 beats/min. This was accompanied by an increase in pacemaker channel (HCN2) but not alpha-MHC or SERCA II messenger RNA levels. Biochemical studies and (31)P-NMR spectroscopy showed significantly lower levels of phosphocreatine and creatine in TG hearts. These results suggest that even mild chronic myocardial thyrotoxicosis, such as may occur in human hyperthyroidism, can cause tachycardia and associated changes in high energy phosphate compounds independent of an increase in SERCA II and alpha-MHC.

Evidence of UCP1-independent regulation of norepinephrine-induced thermogenesis in brown fat.

UNLABELLED: To study the thermal response of interscapular brown fat (IBF) to norepinephrine (NE), urethan-anesthetized rats (1.2 g/kg ip) maintained at 28-30 degrees C received a constant venous infusion of NE (0-2 x 10(4) pmol/min) over a period of 60 min. IBF temperatures (T(IBF)) were recorded with a small thermistor fixed under the IBF pad. Data were plotted against time and expressed as maximal variation (Deltat degrees C). Saline-injected rats showed a decrease in T(IBF) of approximately 0.6 degrees C. NE infusion increased T(IBF) by a maximum of approximately 3.0 degrees C at a dose of 10(4) pmol x min(-1) x 100 g body wt(-1). Surgically thyroidectomized (Tx) rats kept on 0.05% methimazole showed a flat response to NE. Treatment with thyroxine (T(4), 0.8 microg x 100 g(-1) x day(-1)) for 2-15 days normalized mitochondrial UCP1 (Western blotting) and IBF thermal response to NE, whereas iopanoic acid (5 mg x 100 g body wt(-1) x day(-1)) blocked the effects of T(4). Treatment with 3,5, 3'-triiodothyronine (T(3), 0.6 microg x 100 g body wt(-1) x day(-1)) for up to 15 days did not normalize UCP1 levels. However, these animals showed a normal IBF thermal response to NE. Cold exposure for 5 days or feeding a cafeteria diet for 20 days increased UCP1 levels by approximately 3.5-fold. Nevertheless, the IBF thermal response was only greater than that of controls when maximal doses of NE (2 x 10(4) pmol/min and higher) were used. CONCLUSIONS: 1) hypothyroidism is associated with a blunted IBF thermal response to NE; 2) two- to fourfold changes in mitochondrial UCP1 concentration are not necessarily translated into heat production during NE infusion.

Development of compensatory thermogenesis in response to overfeeding in hypothyroid rats.

Intact or surgically thyroidectomized (Tx) adult male Wistar rats, weighing 150-200 g, were fed a standard chow diet (approximately 1.8 Cal/g) or a high calorie (approximately 3.8 Cal/g) diet (cafeteria diet) for up to 30 days. Daily energy intake was about 5-fold higher in the rats fed the cafeteria diet regardless of their thyroid status. The cafeteria diet caused the retroperitoneal white fat pad to increase by approximately 2-fold, the volume of isolated white adipocytes to increase by 2-fold, and the total body fat to increase by a factor of approximately 3, again regardless of thyroid status. It also increased basal metabolic rate by about 20% in intact rats and by about 50% in Tx rats. The brown fat thermal response to norepinephrine (NE) infusion was approximately 2-fold increased in the intact rats fed the cafeteria diet. However, in the Tx rats, the brown fat thermal response to NE was blunted regardless of the dietary regimen adopted. In both intact and Tx rats, the cafeteria diet increased total brown fat mitochondria, uncoupling protein percentage, and total brown fat uncoupling protein by about 3-, 2-, and 5-fold, respectively. Serum leptin levels also increased approximately 4-fold in intact rats fed the cafeteria diet. However, in Tx rats, leptin levels did not change significantly during overfeeding. In conclusion, hypothyroidism caused the brown fat to become unresponsive to NE, even after 1 month on the cafeteria diet. However, these rats were able to increase basal metabolic rate and, as assessed by several different parameters, did not gain fat beyond that observed in intact controls kept on a similar overfeeding schedule.

Thyroxine 5'-deiodination mediates norepinephrine-induced lipogenesis in dispersed brown adipocytes.

In euthyroid rats, maximal sympathetic nervous system stimulation (e.g. during cold exposure) results in a 3- to 4-fold increase in brown adipose tissue lipogenesis, a response that is blunted in hypothyroid rats. To further investigate this phenomenon, the role of local type II 5'-deiodinase (5'-DII) was studied in freshly isolated brown adipocytes. In a typical experiment, 1.5 x 10(6) cells were incubated for up to 48 h in a water-saturated 5% CO2-95% O2 atmosphere. After incubation with medium alone or with different concentrations of T4, T3, and/or norepinephrine (NE), lipogenesis was studied by measuring 1) the rate of fatty acid synthesis as reflected by 3H2O incorporation into lipids and 2) the activity of key rate-limiting enzymes, i.e. acetyl coenzyme A carboxylase and malic enzyme, and the results are reported in terms of DNA content per tube. Lipogenesis decreased progressively over time (approximately 40%) when no additions were made to the incubation medium. T4 or T3 partially prevented that inhibition at physiological concentrations (65 x 10[-9] and 0.77 x 10[-9] M, respectively), whereas a receptor-saturating concentration of T3, (154 x 10[-9] M) doubled the lipogenesis rate. The addition of 10(-6) M NE inhibited lipogenesis acutely (approximately 50% by 12 h) and was followed by a progressive stimulation that reached approximately 2-fold by 48 h, but only in the presence of T4. Furthermore, NE did not attenuate T3 (154 x 10[-9] M)-induced lipogenesis. Both the inhibition and the stimulation of lipogenesis caused by NE showed a strong dose-response relationship within the range of 10(-11)-10(-5) M. The role of local 5'-DII was further tested by incubating brown adipocytes with 10(-6) M NE and T4 (65 x 10[-9] M) in the presence of 100 microM iopanoic acid, a potent inhibitor of 5'-DII. Although iopanoic acid did not affect the T3 stimulation of lipogenesis, it did block the approximately 2-fold stimulation of lipogenesis triggered by NE in the presence of T4, confirming the mediation of 5'-DII in this process. In conclusion, lipogenesis in brown adipose tissue is under complex hormonal control, with key roles played by NE, thyroid hormones, and local 5'-DII. As in other tissues, NE-generated signals acutely (12 h) inhibited lipogenesis. However, the presence of the 5'-DII generated enough T3 to stimulate lipogenesis and gradually reverse the short-lived NE-induced inhibition, leading to the 2- to 3-fold response observed at later time points.

Effects of hypothyroidism on brown adipose tissue adenylyl cyclase activity.

Hypothyroidism profoundly reduces the capacity of brown adipose tissue (BAT) to generate cAMP in response to adrenergic stimulation. Evidence obtained with isolated brown adipocytes suggests a postreceptor defect that offsets the hypothyroidism-induced increase in beta3-adrenergic receptors. The goal of the present studies was to identify the defect in the cAMP generation pathway for which we studied cAMP generation in isolated cells and purified BAT membranes from normal and hypothyroid rats. Studies with adenosine deaminase and the adenosine receptor-1 agonist r-phenyl isopropyl adenosine (R-PIA) show that hypothyroid cells are not more sensitive to adenosine (same EC50) but more inhibited by high concentrations of R-PIA. Pretreatment with pertussis toxin reduced the gap in cAMP generation between eu- and hypothyroid cells and the inhibition mediated by R-PIA, but did not normalize the cAMP response to forskolin in hypothyroid cells. Although purified euthyroid BAT membranes increased cAMP production with GTP concentrations up to submillimolar range, to plateau or slightly decrease at higher levels, hypothyroid membranes were weakly stimulated by low concentrations of GTP and markedly inhibited (>50%) at concentrations > or = 10(-4) M. When assayed at 0.3 mM ATP and 1 microM GTP, hypothyroid membranes actually generated more cAMP in response to forskolin, but this was reversed when GTP concentration was 1 mM. Immunoblotting studies showed no significant effects of hypothyroidism on the abundance of G(alpha)i or Gbeta subunits, and ADP ribosylation of G(alpha)i was only 45% increased in hypothyroidism in contrast to a 2.5-fold increase in hypothyroid white adipose tissue membranes from the same rats. Hypothyroid membranes also exhibited different kinetics regarding ATP, with higher cAMP generation at submillimolar concentrations but less at >1 mM ATP. Actually, at ATP concentrations >0.6 mM, cAMP generation was markedly inhibited in hypothyroid membranes. Fixing the concentration of free Mg++ in these experiments indicates that most of the inhibition seen in hypothyroid membranes is caused by ATP, whereas euthyroid membranes are more sensitive to changes in free Mg++. Ca++ +/- calmodulin did not stimulate adenylyl cyclase (AC) activity. On the contrary, AC activity was inhibited by Ca++ in a concentration-dependent manner, by as low as 100 nM free Ca++, and to greater extent in hypo- than in euthyroid membranes (maximal inhibition 60 vs. 25-30%). Our results suggest that, functionally, hypothyroidism causes a change in the AC of BAT membranes consistent with a relative or absolute increase in the type VI AC (AC-VI). The effects on this AC of nucleotides, Ca++, and Mg++ at concentrations prevailing in the hypothyroid brown adipocyte are probably the major factor in the reduced capacity of these cells to generate cAMP. These results also open the possibility of a novel, differential effect of thyroid hormone on AC expression, and support the concept that thyroid hormone affects the adrenergic signal transduction pathways in a tissue-selective manner.

Hormonal regulation of malic enzyme and glucose-6-phosphate dehydrogenase in brown adipose tissue.

The activities of malic enzyme (ME) and glucose-6-phosphate dehydrogenase (G-6-PDH), two NADPH-generating lipogenic enzymes, were measured in brown adipose tissue (BAT) of rats undergoing various neurohormonal manipulations. Methimazole-induced hypothyroidism doubled the activity of these two enzymes but, surprisingly, triiodothyronine (T3) given to hypothyroid rats caused a time- and dose-dependent stimulation of up to three- to fourfold. Unilateral BAT denervation modestly reduced the activity of these enzymes (approximately 30%) and failed to prevent the stimulation induced by hypothyroidism, whereas growth hormone (GH) successfully blocked this effect of hypothyroidism. Insulin stimulated both enzymes regardless of the thyroid status but failed to abolish the inhibitory effect of GH. In intact rats, cold exposure caused a time-dependent increase in the activity of both ME and G-6-PDH, which reached 5.2- and 3-fold, respectively, after 96 h. This cold-induced stimulation was not observed in hypothyroid rats, but it was restored by physiological doses of thyroxine (800 ng.100 g body wt-1.24 h-1). Replacement with T3 (300 ng.100 g body wt-1.24 h-1), in contrast, did not have this effect. In hypothyroid rats with hemidenervation of BAT, norepinephrine (NE) modestly increased ME and G-6-PDH activities in the denervated side, with little or no effect in the intact side. Receptor-saturating doses of T3 (50 micrograms.100 g body wt-1.day-1 over 48 h) stimulated two- and threefold both enzymes in both sides, reducing or obliterating the effect of denervation. The data suggest a complex neurohormonal regulation of the activity of ME and G-6-PDH in BAT.(ABSTRACT TRUNCATED AT 250 WORDS)

Central role of brown adipose tissue thyroxine 5'-deiodinase on thyroid hormone-dependent thermogenic response to cold.

As judged by the response of uncoupling protein and key enzymes, brown adipose tissue (BAT) is highly dependent upon the local generation of T3 catalyzed by the tissue type II T4 5'-deiodinase (5'-D-II). In hypothyroid rats treated with T3 or T4, the capacity to withstand cold seems better correlated with the normalization of BAT responses than with the liver thyroid status. 5'D-II is activated by cold via sympathetic nervous system (SNS) stimulation, and the activation generates enough T3 to nearly saturate BAT nuclear T3 receptor (NTR) in euthyroid rats. In hypothyroidism, 5'D-II is highly stimulated by the SNS and hypothyroxinemia. In the present studies we have taken advantage of this situation to test 1) the capacity of 5'D-II to maintain nuclear T3 in rats with various degrees of hypothyroxinemia, and 2) the hypothesis that thyroid hormone-dependent BAT-facultative thermogenesis, rather than the effect of thyroid hormone on obligatory thermogenesis (basal metabolic rate), is the basic mechanism by which thyroid hormone confers protection against acute cold exposure. We treated methimazole-blocked rats (undetectable plasma T4 and T3) for a week with either subreplacement doses of T4 (0.5, 1, 2, and 4 micrograms/kg.day) or replacement doses of T4 or T3 (8 or 3 micrograms/kg.day, respectively). Sources and content of BAT nuclear T3 were studied at 25 C and after 48 h at 4 C by labeling the plasmaborne T3 (T3[T3]) with [131I]T3 and the locally generated T3 (T3[T4]) with [125I]T4. Neither the kinetics of nuclear-plasma exchange of T3[T3], the time of appearance of T3[T4] in BAT nuclei, nor NTR maximal binding capacity (0.71 ng T3/mg DNA) was affected by hypothyroidism. Kinetic analyses indicated a maximal BAT NTR occupancy of 40% at euthyroid serum T3 concentrations if T4 is not present. Replacement with T4 normalized both serum T4 and T3, while replacement with T3 normalized serum T3; for all other doses of T4, serum T4 and T3 concentrations were predictably related to the dose. 5'D-II activity decreased with increasing doses of T4, but for each dose of T4, this activity was 2-4 times greater at 4 C than at 25 C. BAT NTR occupancy normalized with 2 micrograms T4/kg in rats maintained at 25 C and with 4 micrograms T4/kg in cold-exposed rats, although in neither condition were serum T4 and T3 normalized nor more than 30% of NTR occupied by plasma T3.(ABSTRACT TRUNCATED AT 400 WORDS)