Phenolic ring deiodination in cultured rat hepatoma cells, and subcellular localization of deiodinases in cultured rat hepatoma, monkey hepatocarcinoma cells and normal rat liver homogenates

The cultured rat hepatoma cell (R117-21B) homogenates metabolized 3,[3′,5′-¹²⁵I]triiodothyronine by phenolic ring deiodination and produced radioactive iodide and 3,3′-diiodothyronine. Thyroxine (T₄) was converted to 3,3′,5-triidothyronine (T₃). The production of ¹²⁵I⁻ presented the deiodinase activity. The optimal pH for phenolic ring deiodination was observed to be pH 6.0–7.0. This enzyme reaction was accelerated by dithiothreitol. Propylthiouracil strongly inhibited the phenolic ring deiodination at 0.1 mM, whereas an effect of 20 mM methylmercaptoimidazol on the deiodination was very weak or absent.Excess unlabeled iodothyronines (T₄, T₃ and 3,5-diiodo-l-thyronine inhibited the phenolic ring deiodination of labeled 3,3′,5′-triiodothyronine, althought their inhibitory effect was slightly different. Triiodothyroacetic acid was a better inhibitor than T₃. Diiodotyrosine did not affect phenolic ring deiodination in cultured rat hepatoma cell homogenates.Phenolic and nonphenolic ring deiodinase activities of cultured monkey hepatocarcinoma cell and rat liver homogenates were also studied by the use of 3,[3′,5′-¹²⁵I]triiodothyronine and [3,5-¹²⁵I]thyroxine, respectively. Both deiodinase activities were observed in particulate fractions (mitochondrial and microsomal) of cultured cell and rat liver homogenates.     

Phenolic and nonphenolic ring deiodinations of iodothyronines in cultured hepatocarcinoma cell homogenate from monkey.

Iodothyronine monodeiodinase activities in homogenates of cultured monkey hepatocarcinoma cells were measured by the deiodination of [3.5-(125)I]-diiodo-L-thyronine or 3-[3',5'-(125)I]triiodo-L-thyronine (phenolic ring-labeled 'reverse' triiodothyronine). The assay system utilized a small ion-exchange column (AG50W-X4, O.9 X approximately 1 cm) to measure 125I-. Both deiodinases were destroyed by boiling for 1 min. Maximal nonphenolic ring deiodination was observed at pH 7.9 whereas maximal phenolic ring deiodination was at pH 6.3. Both reactions were enhanced strongly by dithiothreitol (0.1-5mM), and slightly by 5 mM beta-mercaptoethanol. Phenolic ring deiodination was strongly inhibited by 0.1 mM propylthiouracil. Nonphenolic ring deiodination was accelerated by EDTA (1.2 MM) and inhibited by Mg(2+) (5mM). Methylmercaptoimidazol and Mg(2+), Ca(2+) and Mn(2+) (0.1-1.0 mM) had little or no effect on either reaction, but Zn(2+) (0.1 mM) strongly inhibited both. Both reactions were inhibited by excess iodothyronine analogues at 10 mM to 10 micron M, and thyroxine was shown to be a competitive inhibitor in both cases. On the basis of relative affinities and inhibitory effects, it appears that the order of affinity for the phenolic ring deiodinase is 3,3',5'-triiodo-L-thyronine(rT3) greater than L-thyroxine(T4) greater than 3,5,3'-triiodo-L-thyronine(T3), whereas for the nonphenolic ring deiodinase the order is T3 greater than T4 greater than rT3. Diiodotyrosine did not affect their deiodination.     

Subcellular distribution of iodothyronine 5′-deiodinase in cerebral cortex from hypothyroid rats

We have examined iodothyronine deiodination in subcellular fractions of cerebral cortex obtained from hypothyroid rats. Enzymatic activities were measured at 37°C in the presence of 20 mM dithiothreitol with ¹²⁵I-labeled T₄ and ¹²⁵I-labeled rT₃ as substrate for 5′-deiodination and ¹³¹I-labeled T₃ as the substrate for the 5-deiodinase. Reaction products were separated by descending paper and/or ion-exchange chromatography. Cerebral cortex subcellular fractions were also characterized by marker enzyme analysis and electron microscopy. Under optimal reaction conditions more than 80% of the 5′-deiodinase was recovered after fractionation. Both 5′-deiodinase and (Na⁺ +K⁺-ATPase showed similar subcellular distributions and were enriched approx. 3-fold in the easily sedimenting membrane fraction and nerve terminal plasma membranes. Crude microsomal membranes (6·10⁶g·min pellet) also showed 2-fold enrichment of these enzymes. Nuclei and isolated mitochondria were devoid of deiodinating activity. T₄ and T₃ 5-deiodinating activity was absent in the easily sedimenting membranes and present but not enriched in particulate fractions containing microsomal membranes. These data suggest that iodothyronine 5′-deiodinase is associated with plasma membrane fractions in the cerebral cortex.     

Activation and inactivation of thyroxine by cultured rat hepatoma cells

The metabolism of thyroxine, 3,3′,5-triiodothyronine and 3,3′,5′-triiodothyronine was investigated in rat hepatoma cell cultures (R117-21B). These iodothyronines were labeled with ¹²⁵I in the phenolic ring and the metabolites were analyzed by ion-exchange column chromatography.When thyroxine was incubated with the cells at 37°C, its glucuronide was the major product and a little increase in ¹²⁵I^? was detected. Although 3,3′,5-triiodothyronine was not observed in the incubation medium, this metabolite was clearly identified in the ethanol extract obtained from the cell homogenates after 24 h incubation.This cell line also metabolized labeled 3,3′,5-triiodothyronine added to culture medium. After 24 h incubation, 3,3′,5-triiodothyronine glucuronide was the major metabolite and iodothyronine sulfates were also formed. The sulfates contained, 3,3′,5-triiodothyronine and 3,3′-diiodothyronine sulfates and an unknown component.In the metabolism of 3,3′,5′-triiodothyronine, the cells were very active in carrying out glucuronidation and phenolic ring deiodination, and this metabolism yielded 3,3′,5′-triiodothyronine and 3,3′-diiodothyronine glucuronides. The iodide fraction contained a small amount of 3,3′-diiodothyronine sulfate.These results show that the R117-21B rat hepatoma cells metabolize the thyroid hormones and their analogs by phenolic and nonphenolic ring deiodinations, by glucuronidation and by sulfation.     

Effects of propylthiouracil and methylmercaptoimidazol on metabolism of thyroid hormones by cultured monkey hepatocarcinoma cells.

Monkey hepatocarcinoma cell monolayer cultures (NCLP-6E) metabolized thyroxine, 3,5,3'-triiodothyronine, 3,3',5'-triiodothyronine and 3,3'-diiodothyronine by phenolic and nonphenolic ring deiodinations and sulfation of the deiodinated products, as shown in previous work with this system. The effects of the antithyroid drugs, propylthiouracil (PTU) and methylmercaptoimidazole (MMI), on these processes was investigated. PTU, at 0.1 and 1 mM, inhibited only phenolic ring deiodination. MMI at 1 mM had no effect, but 32 mM inhibited deiodination of both rings as well as sulfation. The findings suggest that the increased serum rT3 level caused by PTU in vivo is the result of decreased rT3 deiodination, in contrast to the increased rT3 production which is caused by starvation.     

Effects of cycloheximide on inverse regulation of phenolic and nonphenolic ring deiodinases in monkey hepatocarcinoma cells

Both phenolic and nonphenolic ring deiodinase activities in monkey hepatocarcinoma cells (NCLP-6E) were increased by addition of serum in a concentration-dependent manner: the stimulatory effect of serum was evident at a concentration as low as 1.5%, and was maximal at 5%. Lineweaver-Burk analysis showed that the increases in the deiodinase activities are due to the increase in Vmax, but not in Km. The addition of cycloheximide at concentrations ranging from 0.1 to 50 micrograms/ml inhibited the stimulatory effect of serum on phenolic ring deiodinase activity progressively. On the other hand, nonphenolic ring deiodinase activity was increased as much as 4-fold by the addition of 0.5-5 micrograms/ml cycloheximide together with 0.5% serum; a high concentration of the drug, 50 micrograms/ml, however, did not elicit such an increase. Actinomycin D at 5 micrograms/ml completely abolished the increase in nonphenolic ring deiodinase activity by serum or cycloheximide. In addition, actinomycin D inhibited the increase in phenolic ring deiodinase activity by serum in a dose-dependent manner at concentrations ranging from 0.05 to 5 micrograms/ml. It is concluded that phenolic and nonphenolic ring deiodinases are regulated by different mechanisms in monkey hepatocarcinoma cells (NCLP-6E).     

Different pathways of iodothyronine 5′-deiodination in rat cerebral cortex

Microsomal fractions of rat cerebral cortex catalyze the 5′-deiodination of 3,3′,5′-triiodothyronine (rT₃) in the presence of thiols such as dithiothreitol. Evidence is presented that two different enzymatic pathways are involved. One of these has a low apparent K_m (2.7 nM) for rT₃, is inhibited by nanomolar concentrations of thyroxine (T₄), but not by up to 1 mM 6-propyl-2-thiouracil (PTU). The other pathway has a high apparent K_m (31 nM) for rT₃, is inhibited by PTU, but not by <1 μM T₄. The relative proportion of rT₃ 5′-deiodination via either pathway depends on thyroid status, with increased contributions from the low-K_m system especially in short-term hypothyroidism.     

Effect of thyroid hormone analogues on the displacement of 125I-L-triiodothyronine from hepatic and heart nuclei in vivo: possible relationship to hormonal activity

The capacity of iodotyrosines and iodothyronine analogues to displace tracer[¹²⁵I] L-3,5,3′ triiodothyronine from specific nuclear binding sites in rat liver and heart was related to the displacement capacity of nonradioactive triiodothyronine. Iodotyrosines and L-3,3′,5′ triiodothyronine (“reverse T₃”) were devoid of displacement activity. Analogues with 3,5 substitution in the “inner” ring and single “bulk” substitution in the 3′ position in the phenolic ring exhibited the strongest displacement activity. When the distribution, fractional removal rates and metabolic conversion of the analogues were taken into account, displacement activity appeared to correlate well with the reported thyromimetic activity. These results support the biologic relevance of the nuclear sites.     

Uptake and metabolism of thyroid hormones by cultured monkey hepatocarconoma cells Effects of potassium cyanide and dinitrophenol

Cultured monkey hepatocarcinoma cells (NCLP-6E) were used to investigate the uptake and metabolism of thyroid hormones. Intracellular accumulation was shown by the failure to acutely release hormone from cells subsequently exposed to serum proteins, and by the metabolic transformation of the hormones to deiodinated products and their sulfates. When hepatocarconoma cell monolayers were studied at hormone concentrations below 10^?10 M, neither KCN nor dinitrophenol inhibited uptake. Taken together with previous findings that uptake was neither saturable nor reduced at low temperature, these results indicate that this process was not active transport. Deiodination of both the phenolic and non-phenolic rings, however, was partially inhibited by KCN but not by dinitrophenol. Sulfation of 3,3′-diiodothyronine and 3′-monoiodothyronine was strongly inhibited by both KCN and dinitrophenol.Uptake of the hormones and their metabolites was also measured in suspended hepatocarcinoma cells and compared with the uptake by normal rat hepatocytes, human fibroblasts and human lymphocytes. In these experiments 1 μM triiodothyronine and 0.47 mM dinitrophenol were used to inhibit deiodination and sulfation, respectively. Uptake was similar in all cell types. Accumulation was highest with 3,5,3′-triiodothyronine, intermediate with other compounds having iodines in both rings, lowest with compounds iodinated in only one ring, and absent with iodothronine sulfates. These findings help to explain the relative rates of metabolism of the iodothyronines and their release from the cells.     

Molecular Mechanism of Photoperiodic Time Measurement in the Brain of Japanese Quail

In most organisms living in temperate zones, reproduction is under photoperiodic control. Although photoperiodic time measurement has been studied in organisms ranging from plants to vertebrates, the underlying molecular mechanism is not well understood. The Japanese quail (Coturnix japonica) represents an excellent model to study this problem because of the rapid and dramatic photoperiodic response of its hypothalamic‐pituitary‐gonadal axis. Recent investigations of Japanese quail show that long‐day‐induced type 2 deiodinase (Dio2) expression in the mediobasal hypothalamus (MBH) plays an important role in the photoperiodic gonadal regulation by catalyzing the conversion of the prohormone thyroxine (T₄) to bioactive 3,5,3′‐triiodothyronine (T₃). The T₃ content in the MBH is approximately 10‐fold higher under long than short days and conditions, and the intracerebroventricular infusion of T₃ under short days and conditions mimics the photoperiodic gonadal response. While Dio2 generates active T₃ from T₄ by outer ring deiodination, type 3 deiodinase (Dio3) catalyzes the conversion of both T₃ and T₄ into inactive forms by inner ring deiodination. In contrast to Dio2 expression, Dio3 expression in the MBH is suppressed under the long‐day condition. Photoperiodic changes in the expression of both genes during the photoinduction process occur before the changes in the level of luteinizing hormone (LH) secretion, suggesting that the reciprocal changes in Dio2 and Dio3 expression act as gene switches of the photoperiodic molecular cascade to trigger induction of LH secretion.     

Rat Brain Type II 5'-Iodothyronine Deiodinase Activity Is Extremely Sensitive to Stress

Abstract: The effects of different kinds of acute stressor on thyroid hormone concentrations and deiodinase activities were investigated in four brain regions (frontal cortex, amygdala, hypothalamus, and cerebellum) and in the pituitaries and livers of adult male rats. Five groups of rats were killed after each of the following stressors: (a) an intraperitoneal injection of saline, (b) intragastric intubation, (c) and (d) two different forms of handling, being grasped as for intraperitoneal injection and being moved from one cage to another, and (e) a 2-h period spent in a slowly rotating drum. Two other groups were placed in the rotating drums for 10 and 19 h (sleep deprivation experiment), respectively. All stressors induced significant (in some cases up to 200%) increases in the activity of type II 5′-iodothyronine deiodinase, which catalyzes the deiodination of the prohormone l -thyroxine (T₄) to the active metabolite 3,3′,5-triiodo-l -thyronine (T₃). As a consequence, the tissue concentrations of T₄ fell, and those of T₃ rose (sometimes by up to 300%). However, these changes were limited to selected areas of the brain that were specific for each stressor and were not seen in all brain regions investigated in any group. No clear-cut effects of stress were seen on the activities of the type III 5-iodothyronine deiodinase isoenzyme, which catalyzes the inactivation of T₃, on liver or serum thyroid hormone concentrations or on liver of brain type I 5′-iodothyronine deiodinase activities. In summary, our results show that even mild and very brief stress can induce marked increases in T₃ concentrations specifically in brain but not in liver or blood. Thus, contrary to common opinion, thyroid hormones may play an important physiological role in stress reactions, at least in tissues that contain type II 5′-iodothyronine deiodinase, such as brain and pituitary.     

Partial characterization of 5′(3′)-ribonucleotide and 3′-ribonucleotide phosphohydrolases from Tradescantia albiflora leaves

Two acid phosphomonoesterases, 5′(3′)-ribonucleotide phosphohydrolase and 3′-ribonucleotide phosphohydrolase, were isolated from Tradescantia albiflora leaf tissue and purified by ammonium sulphate precipitation, gel filtration on Sephadex G-200 and repeated chromatography on DEAE-cellulose. The enzymes differed in their sensitivity to dialysis against 1 mM EDTA; the activity of 5′(3′)-ribonucleotide phosphohydrolase was unaffected, while 3′-ribonucleotide phosphohydrolase showed an increase of 60–90%. Both enzymes were rapidly inactivated above 50°. Their ion sensitivity was identical: 1 m M Zn²⁺ and Fe²⁺ were inhibitors for both by 20–80%; while Mg²⁺, Ca²⁺, Co²⁺, K⁺, Na⁺ at 1–10 mM had no significant effect on the activity of either enzyme. Inorganic phosphate inhibited both enzymes almost completely. EDTA (1 mM) did not inhibit either enzyme; none of the divalent cations tested were enzyme activators. 3′-Ribonucleotide phosphohydrolase hydrolysed both 3′- and 5′-nucleoside monophosphates (3′-AMP, 3′-CMP, 3′-GMP, 3′-UMP, 5′-AMP, 5′-CMP, 5′-GMP, 5′-UMP). 5′(3′)-Ribonucleotide phosphohydrolase showed a preference for the 3′-nucleoside monophosphates. Adenosine 3′,5′-cyclic monophosphate, purine and pyrimidine 2′,3′-cyclic mononucleotides at 0.1–1.OmM did not inhibit the enzymes.     

The effect of propylthiouracil on thyroid-stimulating hormone-induced alterations in iodothyronine secretion from perfused dog thyroids

The aim of this study was to see whether the inhibitory effect of propylthiouracil on thyroidal secretion of 3,5,3′-triiodothyronine (T₃) and 3,3′,5′-triiodothyronine (rT₃) could be reproduced in intensively stimulated thyroids, and to elucidate whether an increase in the fractional deiodination of thyroxine (T₄) to T₃ and rT₃ during iodothyronine secretion might be responsible for the transient fall in the T₄/T₃ and T₄/rT₃ ratios in thyroid secretion seen in the early phase after stimulation of thyroid secretion.For this purpose T₄, T₃ and rT₃ were measured in effluent from isolated dog thyroid lobes perfused in a non-recirculation system using a synthetic hormone free medium. 1 mmol/l propylthiouracil induced a significant reduction in thyroid-stimulating hormone (TSH) stimulated T₃ and rT₃ release while the release of T₄ was unaffected. This supports our previous conclusion that T₄ is partially monodeiodinated to T₃ and rT₃ during thyroid secretion. Infusion of 1 mmol/l propylthiouracil for 30 min or 3 mmol/l propylthiouracil for 120 min did not abolish the transient fall in effluent T₄/T₃ and T₄/rT₃ induced by TSH stimulation. Thus, this phenomenon seems not to depend on intrathyroidal iodothyromine deiodinating processes.     

The crystal structure of a major metabolite of thyroid hormone: 3,3′,5′-triiodo-L-thyronine

Two independent conformations of the thyroinactive thyroid hormone metabolite, 3,3′,5′-triido-L-thyronine (rT₃) were determined by X-ray diffraction methods. The conformations show significant difference in the lettering geometry when compared with those of the thyroactive thyroxine (T₄) and 3,5,3′-triido-L-thyronine (T₃). The diphenyl ether conformation of the two conformers of rT₃ is an anti-skewed one, in which the torsion angels, φ (C5-C4-O4-Cl′) are 8° and ?6°, and φ′ are 86° and 87°. This conformation is in contrast to a twist-skewed one of T₄ and T₃. The difference in the binding abilities between T₄, T₃ and rT₃ to thyroxine binding carrier proteins in serum or to a nuclear receptor protein may be explained by the characteristics solid-state conformations of these metabolites.     

Stimulation by ATP of [3H]dopamine binding to synaptic membrane fractions of canine caudate nucleus

The rate of [³H]dopamine binding to crude synaptic membranes from canine caudate nucleus was considerably increased by 2 mM ATP, 5′-adenylylimidodiphosphate and GTP or by 1 mM 5′-guanylyl-imidodiphosphate, while strongly inhibited by 2 mM ADP and GDP. Half maximal concentrations of [³H]dopamine to bind to the membranes were 1.11 × 10^?7M and 8.75 × 10^?6M in the absence of 4 mM ATP, indicating a negative cooperativity of the dopamine receptor, and 9.25 × 10^?7 M in its presence. Hill coefficient was increased from 0.70 to 1.04 by addition of 4 mM ATP. The optimal concentration of ATP for [³H]dopamine binding was in the range of 0.5 to 5 mM.     

New ionic targets of 3,3′,5′-triiodothyronine at the plasma membrane of rat Sertoli cells

The functions of Sertoli cells, which structurally and functionally support ongoing spermatogenesis, are effectively modulated by thyroid hormones, amongst other molecules. We investigated the mechanism of action of rT₃ on calcium (⁴⁵Ca²⁺) uptake in Sertoli cells by means of in vitro acute incubation. In addition, we performed electrophysiological recordings of potassium efflux in order to understand the cell repolarization, coupled to the calcium uptake triggered by rT₃. Our results indicate that rT₃ induces nongenomic responses, as a rapid activation of whole-cell potassium currents in response to rT₃ occurred in <5 min in Sertoli cells. In addition, the rT₃ metabolite, T₂, also exerted a rapid effect on calcium uptake in immature rat testis and in Sertoli cells. rT₃ also modulated calcium uptake, which occurred within seconds via the action of selective ionic channels and the Na⁺/K⁺ ATPase pump. The rapid response of rT₃ is essentially triggered by calcium uptake and cell repolarization, which appear to mediate the secretory functions of Sertoli cells.     

The localization of phenolic and tyrosyl ring thyroxine deiodination in rat and mouse retina

To elucidate T₄ metabolism in various cell types of rat retina, 5-monodeiodinating and 5′-monodeiodinating activities were studied in retinal cell layers obtained by selective cytotoxic action of monosodium glutamate on bipolar and ganglion cell layers and by iodoacetate effect on photoreceptor cells. Concomitantly these enzyme activities were studied in C3H/HeN mouse retina genetically deprived of photoreceptor cells. Deiodinase activities were low in rat and mouse retina deprived of photoreceptors. The 5′-monodeiodination rate of T₄ was higher than T₄ tyrosyl ring deiodination in cell layers examined and the highest values were found in the photoreceptor cells. Data support the hypothesis that phenolic and tyrosyl ring deiodinase activities are present in the photoreceptor cells. Their reciprocal changes may regulate the nuclear function which in turn controls the rhythmical renewal of rod outer segments.     

Bioenergetic impact of tissue-specific regulation of iodothyronine deiodinases during nutritional imbalance

The regulation of energy homeostasis by thyroid hormones is unquestionable, and iodothyronine deiodinases are enzymes involved in the metabolic activation or inactivation of these hormones at the cellular level. T3 is produced through the outer ring deiodination of the prohormone T4, which is catalyzed by types 1 and 2 iodothyronine deiodinases, D1 and D2. Conversely, type 3 iodothyronine deiodinase (D3) catalyzes the inner ring deiodination, leading to the inactivation of T4 into reverse triiodothyronine (rT3). Leptin acts as an important modulator of central and peripheral iodothyronine deiodinases, thus regulating cellular availability of T3. Decreased serum leptin during negative energy balance is involved in the down regulation of liver and kidney D1 and BAT D2 activities. Moreover, in high fat diet induced obesity, instead of increased serum T₃ and T₄ secondary to higher circulating leptin and thyrotropin levels, elevated serum rT3 is found, a mechanism that might impair the further increase in oxygen consumption.     

Regulation of thyroid hormone metabolism in rat liver fractions

The nature of the conversion of thyroxine (T₄) to triiodothyronine (T₃) and reverse triiodothyronine (rT₃) was investigated in rat liver homogenate and microsomes. A 6-fold rise of T₃ and 2.5-fold rise of rT₃ levels determined by specific radioimmunoassays was observed over 6 h after the addition of T₄. An enzymic process is suggested that converts T₄ to T₃ and rT₃. For T₃ the optimal pH is 6 and for rT₃, 9.5. The converting activity for both T₃ and rT₃ is temperature dependent and can be suppressed by heat, H₂O₂, merthiolate and by 5-propyl-2-thiouracil. rT₃ and to a lesser degree iodide, were able to inhibit the production of T₃ in a dose related fashion. Therefore the pH dependendy, rT₃ and iodide may regulate the availability of T₃ or rT₃ depending on the metabolic requirements of thyroid hormones.     

Selenoenzyme activities in selenium- and iodine-deficient sheep

This study was conducted to evaluate the effects of single and combined deficiencies of selenium and iodine on selenoenzyme activities in sheep. Twenty-four male lambs were assigned to one of four semisynthetic diets: combined deficient A (Se⁻I), Se-deficient B (Se⁻I⁺), I-deficient C (Se⁺I⁻), and basal diet D (Se⁺I⁺). Thyroid hormones (T₃, T₄), thyroid stimulating hormone (TSH), and inorganic iodine (PII) were determined in plasma. Selenium and glutathione peroxidase activity (GSH-Px) were determined in erythrocytes, and tissue samples, including the thyroid, liver, kidney, and brain, were taken for selenoenzyme analysis. Plasma T₃, T₄, and TSH concentrations were similar in all groups. Type I deiodinase (ID-I) activity in liver and kidney remained unchanged in Se or I deficiency. In contrast, hepatic ID-I activity was increased by 70% in combined Se-I deficiency. Thyroidal cystolic GSH-Px (c-GSH-Px) and phospholipid GSH-Px (ph-GSH-Px) activities remained constant in both Se-deficient groups, whereas thyroidal c-GSH-Px activity increased (57%) in I deficiency. Type II deiodinase (ID-II) activity was not detectable in the cerebrum and cerebellum, whereas cerebellum Type III deiodinase (ID-III) activity was decreased in I deficiency and combined Se-I deficiencies. The results of the present study support a sensitive interaction between Se and I deficiencies in sheep thyroid and brain. Furthermore, the lack of thyroidal ID-I activity, the presservation of the thyroidal antioxidant enzymes, and the increases in hepatic ID-I indicate that a compensatory mechanism(s) works toward retaining plasma T₃ levels, mostly by de novo synthesis of T₃ and peripheral deiodination of T₄ in Se- and I-deficient sheep.