Thyroid hormones and their effects: a new perspective

The thyroid hormones are very hydrophobic and those that exhibit biological activity are 3',5',3,5-L-tetraiodothyronine (T4), 3',5,3-L-triiodothyronine (T3), 3',5',3-L-triiodothyronine (rT3) and 3,5',-L-diiothyronine (3,5-T2). At physiological pH, dissociation of the phenolic -OH group of these iodothyronines is an important determinant of their physical chemistry that impacts on their biological effects. When non-ionized these iodothyronines are strongly amphipathic. It is proposed that iodothyronines are normal constituents of biological membranes in vertebrates. In plasma of adult vertebrates, unbound T4 and T3 are regulated in the picomolar range whilst protein-bound T4 and T3 are maintained in the nanomolar range. The function of thyroid-hormone-binding plasma proteins is to ensure an even distrubtion throughout the body. Various iodothyronines are produced by three types of membrane-bound cellular deiodinase enzyme systems in vertebrates. The distribution of deiodinases varies between tissues and each has a distinct developmental profile. Thyroid hormones. (1) the nuclear receptor mode is especially important in the thyroid hormone axis that controls plasma and cellular levels of these hormones. (2) These hormones are strongly associated with membranes in tissues and normally rigidify these membranes. (3) They also affect the acyl composition of membrane bilayers and it is suggested that this is due to the cells responding to thyroid-hormone-induced membrane rigidificataion. Both their immediate effects on the physical state of membranes and the consequent changes in membrane composition result in several other thyroid hormone effects. Effects on metabolism may be due primarily to membrane acyl changes. There are other actions of thyroid hormones involving membrane receptors and influences on cellular interactions with the extracellulara matrix. The effects of thyroid hormones are reviewed and appear to b combinations of these various modes of action. During development, vertebrates show a surge in T4 and other thyroid hormones, as well as distinctive profiles in the appearance of the deiodinase enzymes and nuclear receptors. Evidence from the use of analogues supports multiple modes of action. Re-examination of data from th early 1960s supports a membrane action. Findings from receptor 'knockout' mice supports an important role for receptors in the development of the thyroid axis. These iodothyronines may be better thought of as 'vitamone'-like molecules than traditional hormonal messengers.     

Action of thyroid hormones at the cellular level: the mitochondrial target.

Thyroid hormones exert profound effects on the energy metabolism. An inspection of the early and more recent literature shows that several targets at the cellular level have been identified. Since their effects on the nuclear signalling pathway have already been well-defined and extensively reviewed, this article focuses on the regulation of mitochondrial activity by thyroid hormones. Mitochondria, by virtue of their biochemical functions, are a natural candidate as a direct target for the calorigenic effects of thyroid hormones. To judge from results coming from various laboratories, it is quite conceivable that mitochondrial activities are regulated both directly and indirectly. Not only triiodo-L-thyronine, but also diiodothyronines are active in regulating the energy metabolism. They influence the resting metabolism in rats with 3,5-diiodo-L-thyronine seeming to show a clearer effect.     

Proton nuclear magnetic resonance assignments of thyroid hormone and its analogues

1H NMR data of a series of thyroid hormone analogues, e.g., thyroxine (T4), 3,5,3'-triiodothyronine (T3), 3,3',5'-triiodothyronine (rT3), 3,3'-diiodothyronine (3,3'-T2), 3,5-diiodothyronine (3,5-T2), 3',5'-diiodothyronine (3',5'-T2), 3-monoidothyronine (3-T1), 3'-monoiodothyronine (3'-T1), and thyronine (TO) in dimethylsulfoxide (DMSO) have been obtained on a 300 MHz spectrometer. The chemical shift and coupling constant are determined and tabulated for each aromatic proton. The inner tyrosyl ring protons in T4, T3, and 3,5-T2 have downfield chemical shifts with respect to those of the outer phenolic ring protons. Four-bond cross-ring coupling has been observed in all the monoiodinated rings. However, this long-range coupling does not exist in T4, diiodinated on both rings, and T0, containing no iodines on the rings. There is no evidence that at 30 degrees C these iodothyronines have any motional constraint in DMSO solution. In addition to identification of the hormones, the potential use of some characteristic peaks as probes in binding studies is discussed.     

Metabolism of the thyroid hormones

This review covers the current knowledge about the various metabolic pathways involved in the conversion of thyroid hormones to the thyromimetically active and inactive iodothyronines. The concerted mechanism of systemic and local production of iodothyronines by tissue-specific iodothyronine deiodinase isozymes will ultimately determine the expression of thyroid hormone action. This is exemplified for the regulation of synthesis and release of TSH by iodothyronines at the pituitary level. Iodothyronine metabolites, e.g. Triac, rT3 and T3 amine may modulate TSH secretion, and alterations of local pituitary deiodination (e.g. iopanoate inhibition) influence diurnal TSH secretion without changing TRH-dependent episodic TSH secretion pattern. A summary of structure-activity relationships of greater than 200 naturally occurring and synthetic ligands of rat liver type I iodothyronine deiodinase isozyme propylthiouracil-sensitive) in vitro allows the design of iodothyronine analogues which either serve as specific substrates or antagonists of iodothyronine binding and metabolizing proteins. Furthermore, a complete picture of the ligand-complementary active site of the type I isozyme can be derived. A synthetic 'structurally optimized' iodothyronine-analogue flavonoid inhibitor of the type I deiodinase is able to displace T4 from binding to thyroxine-binding prealbumin and leads to unexpected organ-specific alterations of thyroid hormone metabolism and expression of thyroid hormone actions in an animal model. Therefore, for a complete understanding of thyroid hormone metabolism and action, thyroid hormone transport, cellular compartmentalization, and alternate pathways also have to be considered.     

Effect of hypothyroidism on pathways for iodothyronine and tryptophan uptake into rat adipocytes

Adipocytes are an important target tissue for thyroid hormone action, but little is known of the mechanisms of thyroid hormone entry into the cells. The present results show a strong interaction between transport of iodothyronines [L-thyroxine (T4), L-triiodothyronine (T3), reverse T3 (rT3)], aromatic amino acids, and the System L amino acid transport inhibitor 2-amino[2,2,1]heptane-2-carboxylic acid (BCH) in white adipocytes. System L appears to be a major pathway of iodothyronine and large neutral amino acid entry into these cells in the euthyroid state. We also demonstrate expression of the CD98hc peptide subunit of the System L transporter in adipocyte cell membranes. Experimental hypothyroidism (28-day propylthiouracil treatment) has no significant effect on System L-like transport of the amino acid tryptophan in adipocytes. In contrast, uptake of T3 and especially T4 is substantially reduced in adipocytes from hypothyroid rats, partly due to reduction of the BCH-sensitive transport component. Transport of iodothyronines and amino acids in adipocytes therefore becomes decoupled in the hypothyroid state, as occurs similarly in liver cells. This may be due to downregulation or dissociation of iodothyronine receptors from the System L transporter complex. Regulation of iodothyronine turnover in fat cells by this type of mechanism could contribute significantly to modulation of T4-T3/rT3 metabolism in the hypothyroid state.     

Thyroid hormones increase liver and muscle thermogenic capacity in the little buntings (Emberiza pusilla)

Thyroid hormones can increase energy expenditure and stimulate basal thermogenesis by lowering metabolic efficiency. In the present study, we examined the effects of thyroid hormones on basal heat production as well as on several physiological and biochemical measures indicative of thermogenic capacity to test our hypothesis that thyroid hormones stimulate increases in thermogenesis in little buntings. Little buntings that fed on thyroxine (T₄)–laced poultry food of 3 and 5 ppm concentrations showed increases in basal metabolic rate (BMR) during the 3-week acclimation. At the end, these buntings had lower body weights, higher levels of contents of mitochondrial protein, state 4 respiration and cytochrome c oxidase activity in liver and muscle, and higher concentrations of serum triiodothyronine (T₃) and T₄ compared to control buntings. These results support the argument that thyroid hormones play an important role in the regulation of thermogenic ability in buntings by stimulating mitochondrial respiration and enzyme activities associated with aerobic metabolism.     

甲状腺激素对白头鹎基础产热的影响

甲状腺激素对动物的基础产热有调节作用,甲状腺活性的增加往往与基础代谢的增加相伴行。通过每日饲喂甲状腺素(T4)研究了甲状腺机能亢进对白头鹎(Pycnonotus sinensis)代谢产热的影响。代谢率的测定采用封闭式流体压力呼吸计测定,细胞色素C氧化酶(COX)采用铂氧电极-溶氧仪测定,反应温度为30℃,肝脏和肌肉的线粒体状态4呼吸采用铂氧电极-溶氧仪测定,反应温度为30℃,线粒体蛋白的测定以牛血清蛋白作为标准,采用Folin-phenol方法,测定肝脏和肌肉组织的蛋白质含量。与对照组相比,甲亢组的基础代谢率(BMR)明显升高;肝脏及肌肉组织状态4呼吸增加;肝脏和肌肉线粒体的COX活力升高。     

Rapid modulation of TRH-like peptides in rat brain by thyroid hormones

Recent identification of membrane receptors for T4, T3, 3,5-T2, and 3-iodothyronamine that mediate rapid physiologic effects of thyroid hormones suggested that such receptors may supplement the regulation of TRH and TRH-like peptides by nuclear T3 receptors. For this reason 200 g male Sprague-Dawley rats received daily i.p. injections of PTU or T4. Levels of TRH and TRH-like peptides were measured 0, 2 h or 1, 2, 3, or 4 days later. Rapid increases or decreases in TRH and TRH-like peptide levels were observed in response to PTU and T4 treatments in various brain regions involved in mood regulation. Significant effects were measured within 2 h of T4 injection. Nuclear T3 receptor-mediated changes in gene expression altering translation, post-translational processing and constitutive release of peptides require more than 2 h. We conclude that non-genomic mechanisms may contribute to the psychiatric effects of thyroid disease and thyroid hormone adjuvant treatment for major depression.     

Effect of thyroid hormones and their analogues on the mitochondrial calcium transport activity.

In this paper the authors studied the effects of thyroid hormones and their structural analogues on the mitochondrial calcium transport activities. The thyroid hormones, 3,5,3' L-triiodothyronine (LT3) and 3,5,3'5' L-tetraiodothyronine (LT4) at physiological intracellular concentrations between 7.2 and 9 nM, decouple total Ca++ transport, as well as inhibit the passive transport of Ca++, either due to oxidation of pyruvate, malate or succinate or after inhibition with rotenone. The optical isomers 3,5,3' D-triiodothyronine (DT3) and 3,5,3',5' D-tetraiodothyronine (DT4) are less effective at all the used concentrations. Furthermore the structural analogues 3,3',5' L-triiodothyronine (LrT3), 3,5-dicloro, 3',5' L-diiodothyronine (LDiClT2) and 3,5 L-diiodothyronine (LT2) furnished even less effects on the same activities. The effect of the thyroid hormones and of their structural analogues has revealed that the mitochondrial calcium transport may be influenced both by a stereospecific interaction between hormones and protein ligands and by a lipophilic chaotropic action on the mitochondrial membranes lipids. In this context it is interesting to consider that both thyroid hormones and Ca++ transport activity are interacting with the energetic metabolism by means of phosphorylation and substrate oxidation mechanism.     

Sulfation of iodothyronines by recombinant human liver steroid sulfotransferases.

Sulfation is an important pathway in the metabolism of thyroid hormones. Sulfated iodothyronines are elevated in nonthyroidal illnesses and in the normal human fetal circulation. We assayed and characterized COS-1 cell expressed recombinant human liver dehydroepiandrosterone sulfotransferase (DHEA ST or SULT2A1) and estrogen sulfotransferase (EST or SULT1E1) activities for the first time with triiodothyronine (T(3)) as the substrate. Several biochemical properties that included apparent K(m) values, thermal stabilities, and responses to the inhibitors 2, 6-dichloro-4-nitrophenol and NaCl were tested. SULT2A1, a member of the hydroxysteroid sulfotransferase family, used 3,3'-T(2) more readily than T(3) and 3,5-T(2) as substrates, but had the lowest apparent K(m) value for T(3) of any reported human SULT. SULT1E1, a member of the phenol sulfotransferase family, used 3,3'-T(2) and rT(3) more readily than T(3), and also displayed the greatest specificity for T(4) among human SULTs. SULT2A1 may contribute more to iodothyronine sulfation than previously suspected. Potential roles of both steroid sulfotransferases in the enhanced sulfation of nonthyroidal illnesses and fetal development invite further investigation.     

Thyroid hormones regulate lipid metabolism in a teleost Anabas testudineus (Bloch)

We compared the long-term action of 3,5,3′-triiodo-l-thyronine (T₃) and 3,5-diiodo-l-thyronine (T₂) on lipid metabolism in a teleost Anabas testudineus. Among the six groups of animals used in this experiment, except for the control group, all received 6-propylthiouracil (6-PTU) to create a hypothyroid state in order to analyse the action of iodothyronines on lipid metabolism. Injections of 6-PTU reduced T₃ concentration in the circulation by 79.6% and injections of iodothyronines enhanced the level of T₃ in the plasma, and a maximum increase was observed in T₃ (500 ng)-treated specimens. Analysis of lipogenic enzymes in liver and heart showed that a tissue-specific variation exists in the action of thyroid hormones and, in many cases, activity is higher in T₂-treated groups. Analysis of various lipid classes showed that long-term administration of T₂ is also effective in producing a comparable effect with that of T₃ on lipid metabolism.     

Effect of thyroxine in vitro on the transmembrane potential of rat liver mitochondria

It has been shown in in vitro experiments that a certain latent period after the addition of thyroxine (T4) and triiodothyronine (T3) was necessary for the manifestation of their effects on transmembrane potential (TMP) of the rat liver mitochondria. The duration of the lag-period decreased upon an increase in the concentrations of these hormones, and T4 at a dose of 2.10(-4) M produced a fall in TMP immediately after its addition. The rate of TMP fall was in proportion with the concentrations of thyroid hormones introduced into the cell, with T3 30-40% more effective than T4. It was established that the action of I2 resembled that of thyroid hormones, namely, a fall in TMP, mitochondrial swelling, activation of transhydrogenase Kl was ineffective. It is suggested that the appearance of the lag-period upon the action of thyroid hormones might be explained by the period of time necessary for the formation of the active iodine forms, as well as by the formation of fatty acids (donators of H+) by mitochondrial phospholipases. All these factors lead to TMP fall resulting in decreased formation of sufficient ATP quantities in mitochondria.     

Short-term effects of thyroid hormones on Na+-K+-ATPase activity of chick embryo hepatocytes during development: focus on signal transduction

Nongenomic effects of thyroid hormones on Na+-K+-ATPase activity were studied in chick embryo hepatocytes at two different developmental stages, 14 and 19 days of embryonal age, and the signal transduction pathways involved were characterized. Our data showed the following. 1) 3,5,3'-Triiodo-L-thyronine (T3) and 3,5-diiodo-L-thyronine (3,5-T2) rapidly induced a transient inhibitory effect on the Na+-K+-ATPase; the extent and duration depended on the developmental age of the cells. 2) 3,5-T2 behaved as a true hormone and fully mimicked the effect of T3. 3) Thyroxine had no effect at any of the developmental stages. 4) The inhibition of Na+-K+-ATPase was mediated by activation of protein kinase A, protein kinase C, and phosphoinositide 3-kinase, suggesting several modes of modulation of ATPase activity through phosphorylation at different sites. 5) The MAPK pathway did not seem to be involved in the early phase of hormone treatment. 6) The nonpermeant analog T3-agarose inhibited Na+-K+-ATPase activity in the same way as T3, confirming that hormone signaling initiated at a receptor on the plasma membrane. From these results, it can be concluded that the cell response mechanisms change rapidly and drastically within the early phase of embryo growth. The differences found at the two stages probably reflect the different roles of thyroid hormones during development and differentiation.     

The relationship between the structure and activity of rat skeletal muscle mitochondria after thyroidectomy and thyroid hormone treatment

The fine structure of rat gastrocnemius muscle fibers has been studied after changes were induced in the basal metabolic rate (BMR) by thyroidectomy and L-thyroxine administration under anabolic conditions. Biochemical analysis of skeletal muscle mitochondrial respiration and phosphorylation from the same tissue preparations has been summarized, details having been published earlier (3). As estimated from electron micrographs, the total amount of mitochondria from thyroidectomized animals was enlarged 1.5 times over that from normal controls. The total amount of mitochondria from thyroidectomized or normal animals made hypermetabolic with thyroxine was increased 2.5 to 3.5 times over that from their corresponding controls. In all cases, there was an increase in the mitochondrial population and the profile ratio of cristae to matrix was also considerably increased, thus indicating both relative and absolute enlargements of the entire surface of the cristae per unit fiber. The major structural changes persisted for at least 3 weeks after the cessation of thyroxine treatment, by which time the elevated mitochondrial respiratory and phosphorylative activity had declined to normal values. The hypertrophy and increase in mitochondrial population was more prominent in the perinuclear and subsacrolemmic regions near blood vessels than in the interstices of the fibrils. The very long interfibrillar mitochondria found in both the hypo- and hypermetabolic tissues are more likely to be derived from outgrowths of the original mitochondria rather than from a fusion of smaller ones. These findings are compatible with the ideas expressed elsewhere (see 1, 3, 10) that, under conditions close to the physiological, thyroid hormones control mitochondrial metabolic activity by a subtle alteration in mitochondrial composition with respect to their respiratory and phosphorylative constituents. The possible application of using thyroid hormones in the study of biogenesis of mitochondria and the synthesis of mitochondrial constituents are discussed.     

Synthesis of side chain-modified iodothyronines

New side chain-modified iodothyronines have been synthesized. They include: 1-[4-(4-hydroxyphenoxy)-3,5-diiodophenyl]-1,2-ethanediol (T2EG); alpha-hydroxy-4-(4-hydroxyphenoxy)-3,5-diiodobenzeneacetic acid (T2HAA) and their 4-methyl ether derivatives (MT2EG, MT2HAA); 1-[4-(4-hydroxyphenoxy)-3,5-diiodophenyl]-2-aminoethanol (T2EA); 1-[4-(4-hydroxy-3-iodophenoxy)-3,5-diiodophenyl]-1,2-ethaned iol (T3EG); 1-[4-(4-hydroxy-3-iodophenoxy)-3,5-diiodophenyl]-2-aminoetha nol (T3EA); and alpha-hydroxy-4-(3-iodo-4-hydroxyphenoxy)-3,5-diiodobenzeneacet ic acid (T3HAA). These model compounds are being used to study thyroid hormone metabolism and to determine structure-activity relationships of iododiphenylether derivatives.     

A measurable consequence of the Mitchell theory of phosphorylation

Thyroid hormones elevate the protonic electrochemical potential difference across the liver mitochondrial respiratory membrane, which may in turn enhance the organelle's oxidative capacity (Shears &; Bronk,1979). Such an effect can explain many of the consequences of the short-term interaction of the thyroid gland with mitochondria. There are several possible mechanisms by which this hormone action could arise, and it may constitute a significant and novel means of regulating cellular metabolism.     

自愿转轮运动对雄性长爪沙鼠体重和能量代谢的影响

运动是影响动物能量平衡和体重变化的重要因素之一。为研究自愿转轮运动对体重和能量代谢的影响,我们监测了8 周自愿转轮运动过程中,雄性长爪沙鼠的体重、能量摄入、消化率、静止代谢率(RMR) 和非颤抖性产热(NST)的变化,以及8 周后的体脂含量、血清甲状腺激素(T3、T4 )和瘦素(leptin)水平的变化等。结果发现,8 周自愿转轮运动增加了长爪沙鼠的体重和能量摄入以及血清瘦素水平(血清瘦素浓度比对照组高27% ),但对消化率、RMR 和褐色脂肪组织的线粒体蛋白浓度等没有明显影响。尽管体脂含量和血清T₃ 和T₄ 没有显著差异,但运动组体脂含量比对照组高33%,血清T₃ 和T₄ 水平分别比对照组低10% 和38%。血清瘦素浓度与体脂重量呈正相关。因此,自动转轮运动并没有降低动物的体重和体脂含量,但瘦素和甲状腺素在雄性长爪沙鼠能量代谢和能量平衡中的作用尚需进一步确定。