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Posts Tagged ‘hypothyroid’


Thyroid Function and Disorders

Writer and Curator: Larry H. Bernstein, MD, FCAP 

Normal thyroid function is maintained by endocrine interactions between the hypothalamus, anterior pituitary and thyroid gland [Matfin, 2009]. Iodide is transported across the basement membrane of the thyroid cells by an intrinsic membrane protein called the Na/I symporter (NIS). At the apical border, a second iodide transport protein called pendrin moves iodide into the colloid, where it is involved in hormono-genesis. Once inside the follicle, most of the iodide is oxidized by the enzyme thyroid peroxidase (TPO) in a reaction that facilitates combination with a tyrosine molecule to ultimately form thyroxine (T4) and triiodothyronine (T3). Thyroxine is the major thyroid hormone secreted into the circulation (90%, with T3 composing the other 10%). There is evidence that T3 is the active form of the hormone and that T4 is converted into T3 before it can act physiologically.

All of the major organs in the body are affected by altered levels of thyroid hormone. These actions are mainly mediated by T3. In the cell, T3 binds to a nuclear receptor, resulting in transcription of specific thyroid hormone response genes.

Maternal thyroid hormones are essential for neural development in zebrafish.

Marco A Campinho, João Saraiva, Claudia Florindo, Deborah M Power Molecular endocrinology (Baltimore, Md.) 05/2014;
http://dx.doi.org:/10.1210/me.2014-1032

ABSTRACT Teleost eggs contain an abundant store of maternal thyroid hormones (THs) and early in zebrafish embryonic development all the genes necessary for TH signalling are expressed. Nonetheless the function of THs in embryonic development remains elusive. To test the hypothesis that THs are fundamental for zebrafish embryonic development an MCT8 knockdown strategy was deployed to prevent maternal TH uptake. Absence of maternal THs did not affect early specification of the neural epithelia but profoundly modified later dorsal specification of the brain and spinal cord as well as specific neuron differentiation. Maternal THs acted upstream of pax2a, pax7 and pax8 genes but downstream of shha and fgf8a signalling. The lack of inhibitory spinal cord interneurons and increased motorneurons in the MCT8 morphants is consistent with their stiff axial body and impaired mobility. MCT8 mutations are associated with X-linked mental retardation in humans and the cellular and molecular consequences of MCT8 knockdown during embryonic development in zebrafish provides new insight into the potential role of THs in this condition.
Relationship between thyroid status and renal function in a general population of unselected outpatients

Giuseppe Lippi, Martina Montagnana, Giovanni Targher, Gian Luca Salvagno, Gian Cesare Guidi
Clin Biochem May 2008; 41(7–8): 625-627

When compared with euthyroid subjects, those with TSH < 0.2 mIU/L and > 2.5 mIU/L had increased and decreased estimated glomerular filtration rate (e-GFR), respectively. TSH levels were an independent predictor of e-GFR.

Serum Thyroid-Stimulating Hormone Measurement for Assessment of Thyroid Function and Disease

Douglas S. Ross
Endocr and Metab Clinics of N Am, Jun 2001; 30(2, 1): 245-264

Thyrotropin, or thyroid-stimulating hormone (TSH), is one of a family of glycoprotein hormones including luteinizing hormone (LH), follicle-stimulating hormone (FSH), and human chorionic gonadotropin (hCG) that share a common α-subunit and a unique β-subunit. Pituitary TSH regulates the secretion of the thyroid hormones T4 (thyroxine) and T3 (triiodothyronine). TSH secretion, in turn, is controlled through negative feedback by thyroid hormone on the pituitary thyrotrope. This relationship is negative log-linear. Small changes in serum free thyroid hormone concentrations result in large changes in serum TSH concentrations, and even subtle changes in thyroid hormone production are best assessed by measurement of serum TSH . Until the late 1980s, the detection limit of TSH assays was within the normal range, and these first-generation TSH assays were useful only for the detection of hypothyroidism. Free T4 measurements were primarily used for assessing thyroid function despite the technical difficulties in free thyroid hormone measurements owing to abnormal binding proteins, changes in binding protein concentrations, and the effects of drugs and illness on thyroid hormone binding. With the use of sensitive second- and third-generation TSH assays, TSH measurement has emerged as the single most useful test of thyroid function. It is widely and appropriately used as a screening test. Unfortunately, the trend has been to rely on TSH measurements alone for the assessment of complicated thyroid disease and patients undergoing treatment for thyroid dysfunction. This article focuses on the potential and real limitations of TSH measurement.
Correlation of creatinine with TSH levels in overt hypothyroidism — A requirement for monitoring of renal function in hypothyroid patients?

Vandana Saini, Amita Yadav, Megha Kataria Arora, Sarika Arora, Ritu Singh, Jayashree Bhattacharjee
Clin Biochem  Feb 2012; 45(3): 212-214

Highlights
► Increase serum creatinine levels in both subclinical and overt hypothyroidism. ► Creatinine levels progressively increase with increasing degree of hypothyroidism. ► Increase in creatinine correlated with TSH levels in overt hypothyroid subjects. ► Regular monitoring of renal function is required in hypothyroid patients.

Renal function is influenced by thyroid status. Therefore, this study was done to determine the relationship between renal function and different degrees of thyroid dysfunction.
Design and methods
Thyroid and kidney function tests were analyzed in 47 patients with overt (TSH ≥ 10.0 μIU/L) and 77 patients with subclinical hypothyroidism (TSH 6.0–9.9 μIU/L) in a cross-sectional study. These were compared with 120 age- and sex-matched euthyroid controls.
Results
Overt hypothyroid subjects showed significantly raised serum urea, creatinine and uric acid levels as compared to controls whereas subclinical hypothyroid patients showed significant increased levels of serum urea and creatinine levels. TSH showed significant positive correlation with creatinine and uric acid values and, fT4 had a negative correlation with uric acid in overt hypothyroidism.
Conclusion
Hypothyroid state is associated with significant derangement in biochemical parameters of renal function. Hence the renal function should be regularly monitored in hypothyroid patients.

  1. Ability of Serum Thyroid-Stimulating Hormone Levels to Reflect Peripheral and Central Thyroid Hormone Action Appropriately
  • Uncertainty Owing to Heterogeneity of T4 Deiodinases
  • Uncertainty Owing to Heterogeneity of T3 Receptors
  • Uncertainty Owing to Resetting of the Threshold for Negative Feedback
  1. Clinical Utility of Thyroid-Stimulating Hormone Measurement
  2. Screening for Thyroid Disease and Assessment of Patients Suspected of Having Thyroid Disease
  • Limitations of Thyroid-Stimulating Hormone Testing in Patients with Known Thyroid Disease Central Hypothyroidism
  • Thyrotoxicosis Owing to Inappropriate Thyroid-Stimulating Hormone Secretion
  • Monitoring Thyroid Hormone Therapy
  • Patients Treated for Hyperthyroidism
  1. The Pituitary-Thyroid Axis in Nonthyroidal Illness
  • Measurement of Thyroid-Stimulating Hormone
  • Drugs that Affect Serum Thyroid-Stimulating Hormone Concentrations

Investigations into the etiology of elevated serum T3 levels in protein-malnourished rats

Robert C. Smallridge, Allan R. Glass, Leonard Wartofsky, Keith R. Latham, Kenneth D. Burman
Metabolism, V June 1982; 31(6): 538-542

Thyroid function studies and the peripheral metabolism of thyroid hormone were examined in rats fed a low protein diet (9% casein) for 4–8 wk. Compared to animals fed a normal protein diet ad libitum, both the low protein rats and a pair-fed control group weighed less at the end of the study. However, serum total T3 levels were significantly higher only in the protein deficient rats. The elevated serum T3 was not explainable by enhanced peripheral T4 to T3 conversion, as there was no evidence of any change in hepatic or renal 5′-deiodinase activity when homogenates were examined for conversion of T4 to T3, reverse T3 to 3,3′-diiodothyronine, or 3′,5′-diiodothyronine to 3′-monoiodothyronine. Neither was there an effect on hepatic T3 receptor maximal binding capacity (204 ± 24 versus 168 ± 15 fmol/mg DNA control) or binding affinity (2.07 ± 0.38 versus 2.49 ± 0.24 × 10−10 M control). In two separate experiments the dialyzable fraction of T3 was significantly lower in the low protein group while free T3 concentrations were unchanged or reduced. In contrast, serum total and free T4 were either normal or reduced and dialyzable T4 was unaffected by protein deficiency. We conclude that while serum total T3 is elevated in rats chronically fed a low protein diet, this elevation is not due to enhanced T4 to T3 conversion. Rather, the increased T3 levels can be accounted for by a striking alteration in protein binding to T3. Moreover, the failure to demonstrate similar changes in serum total and dialyzable T4 suggests that in the rat, protein deficiency has different effects on binding to the two major thyroid hormones. Dietary induced changes in serum thyroid hormone binding must be kept in mind in nutrition studies in the rat.

Role of thyrotropin in metabolism of thyroid hormones in nonthyroidal tissues

Udaya M. Kabadi
Metabolism, Jun 2006; 55(6): 748-750

T4 conversion into T3 in peripheral tissues is the major source of circulating T3. However, the exact mechanism of this process is ill defined. Several in vitro studies have demonstrated that thyrotropin facilitates deiodination of T4 into T3 in liver and kidneys. However, there is a paucity of in vitro studies confirming this activity of thyrotropin. Therefore, this study was conducted to examine the influence of thyrotropin on thyroid hormone metabolism in nonthyroidal tissues. We assessed T4, T3, reverse T3 (rT3), and T3 resin uptake (T3RU) responses up to 12 hours at intervals of 4 hours in 6 thyroidectomized female mongrel dogs rendered euthyroid with LT4 replacement therapy before and after subcutaneous (SC) administration of bovine thyrotropin (5 U) on one day and normal saline (0.5 mL) on another in a randomized sequence between 08:00 and 09:00 am. Euthyroid state after LT4 replacement was confirmed before thyrotropin administration. Serum T4, T3, rT3, and T3RU all remained unaltered after SC administration of normal saline. No significant alteration was noted in serum T3RU values on SC administration of thyrotropin. However, serum T3 rose progressively reaching a peak at 12 hours with simultaneous declines being noted in both serum T4 and rT3 concentrations (P < .05 vs prethyrotropin values for all determinations). The changes after SC administration were significantly different (P < .001) in comparison to those noted on SC administration of normal saline. Thyrotropin may promote both the conversion of T4 to T3 and metabolism of rT3 into T2 in nonthyroidal tissues via enhancement of the same monodeionase.

Effects of growth hormone administration on fuel oxidation and thyroid function in normal man

Jens Møller, Jens O.L. Jørgensen, Niels Møller, Jens S. Christiansen, Jørgen Weeke
Metabolism, Jul 1992;  41(7): 728-731

In a randomized, double-blind, placebo-controlled, cross-over study, we examined the effects of 14 days of growth hormone (GH) administration (12 IU/d subcutaneously) on energy expenditure (EE), respiratory exchange ratio (RER), and thyroid function in 14 normal adults of normal weight (eight men and six women). EE (kcal/24 h) was significantly elevated after GH administration (2,073 ± 392, [GH], 1,900 ± 310, [placebo], P = .01). RER was significantly lowered during GH administration (0.73 ± 0.04 v 0.78 ± 0.06, P = .02), reflecting increased oxidation of lipids. Total triiodothyronine (TT3) (nmol/L) and free T3 (FT3) (pmol/L) increased significantly during GH (TT3: 1.73 ± 0.06 [GH], 1.48 ± 0.08 [placebo], P = .01; FT3: 6.19 ± 0.56 [GH], 5.49 ± 0.56 [placebo], P = .01). Concomitantly, an insignificant decrease in reverse T3 (rT3) (nmol/L) was observed (0.07 ± 0.01 [GH], 0.15 ± 0.01 [placebo], P = .08). GH caused a highly significant increase in T3/thyroxine (T4 (×100) ratio (1.84 ± 0.12 [GH], 1.37 ± 0.06 [placebo]). Serum thyrotropin (TSH) was not significantly changed by GH. No changes in total thyroxine (TT4) (nmol/L) (98 ± 6 [GH], 111 ± 8 [placebo], P = .40) and free thyroxine (FT4) (pmol/L) (17.4 ± 1.3 [GH], 18.6 ± 1.1 [placebo], P = .37) after 14 days of GH administration were observed. In conclusion, 2 weeks of GH administration increases EE and lipidoxidation. This finding may partly be mediated by an increase in peripheral T4 to T3 conversion.

Studies on the deiodination of thyroid hormones in Xenopus laevis tadpoles

Helen Robinson, Valerie Anne Galton
Gen Compar Endocr, Sept 1976; 30(1): 83-90

Liver and tail tissues from Xenopus laevis tadpoles possess deiodinating systems capable of degrading both thyroxine (T4) and 3,5,3′-triiodothyronine (T3). Deiodinating activity in liver remains at a constant level throughout late development and metamorphosis with the exception of a transient increase at stage 59, the onset of metamorphosis. Tail activity remains constant during development but rises sharply during metamorphosis when the tail is undergoing regression. In contrast to these findings on spontaneously metamorphosing tadpoles, tail tips induced to regress in vitro do not exhibit any rise in deiodinating activity, even when the tail tips are undergoing extensive autolysis. These results indicate that, while a rise in deiodinating activity may coincide temporarily with hormone action during metamorphosis, the two phenomena may be separated. The deiodinating activity present in tadpole tissues appears to be enzymic and possesses properties characteristic of peroxidase activity. The reaction catalyzed by this mechanism does not appear to involve monodeiodination and hence cannot be considered a mechanism for the peripheral conversion of T4 to T3.

Mechanisms governing the relative proportions of thyroxine and 3,5,3′-triiodothyronine in thyroid secretion

Peter Laurberg
Metabolism, Apr 1984; 33(4): 379-392

In subjects with normal thyroid function only a minor part of circulating 3,5,3′-triiodothyronine (T3) originates directly from the thyroid; the majority is produced in the peripheral tissues by deiodination of thyroxine (T4). However, T3 of thyroidal origin constitutes a relatively high fraction of the total T3 produced in many patients with thyroid hyperfunction or hypofunction. Such a relatively high T3 content in the secretion of the thyroid could be caused by a low T4T3 ratio in thyroglobulin. Severe iodine deficiency is a well-known inducer of a low T4T3 ratio, but a low T4T3 ratio can also be produced independent of the iodine content. This is seen in in vitro studies of thyroglobulin iodination when small amounts of DIT are added to the incubation mixture and in vivo in TSH-treated animals and in patients with Graves’ disease. Another mechanism for high thyroidal secretion of T3 could be an enhanced fractional deiodination of T4 to T3 in the thyroid. In vitro thyroid perfusion studies have shown that the T3 content of thyroid secretions is higher than would be expected from the T4T3 ratio of thyroid hydrolysate and that the major mechanism is deiodination of T4 to T3. Thyroxine deiodinases are also present in the human thyroid, and the amount of T4 deiodinase is enhanced in the thyroids from patients with medically treated Graves’ disease and in the hyperstimulated thyroids of rats. Other factors of possible importance for the mixture of T3 and T4 secreted by the thyroid are a relatively faster liberation of T3 than of T4 from thyroglobulin during partial hydrolysis (this faster release of T3 is probably the mechanism behind the more “rapid” secretion of T3 than of T4), or some kind of thyroid heterogeneity leading to pinocytosis and hydrolysis of thyroglobulin with a lower T4T3 ratio than that of average thyroglobulin.

Starvation-induced alterations of circulating thyroid hormone concentrations in man

Thomas J. Merimee, E.S. Fineberg
Metabolism Jan 1976; 25(1): 79-83

Serum concentrations of triiodothyronine (T3), thyroxine (T4), and TSH were examined in seven men and seven women of normal weight during a 60-hr fast. Similar studies were conducted in two women who received daily for 1 mo before and during a similar fast, 0.4 mg and 0.5 mg of l-thyroxine.
The serum concentrations of T3 decreased in each of the untreated normal subjects (sign test of significance, p < 0.001). The mean control concentration of T3 in women was 152 ± 9 ng100 ml (X ± SEM); after 24 hr of fasting, 131 ± 31 ng100 ml; and at the termination of the fast, 90 ± 15 ng100 ml. The latter value differed from the control value with a p value of < 0.01. Similar changes of T3 concentration occurred in men (mean basal T = 160 ± 11 ng100 ml; mean at termination of fast = 87 ± 16 ng100 ml). The range of decrease for T3 in all subjects varied from 24% to 55%.
The mean T4 concentration at the beginning of the fast was  6.9 ± 0.9, and at the termination of the fast, 7.5 ± 0.6 (p = NS). TSH concentrations remained unchanged (Control, 3.8 ± 0.45 μU/ml; at 60 hr, 4.0 ± 0.26 μU/ml, p = NS).
Studies in two women who received, before and during a fast, T4, indicate that a decreased peripheral conversion of T4 to T3 is the most likely mechanism responsible for this change.

Effect of estrogens on thyroid function. II. Alterations in plasma thyroid hormone levels and their metabolism

Ramesh C. Sawhney, Indra Rastogi, Gopal K. Rastogi
Metabolism Mar 1978; 27(3): 279-288

The circulating levels of total triiodothyronine (TT3), thyroxine (TT4, and T4-bbinding globulin (TBG) and the kinetics of T3 and T4 were studied in five menstruating rhesus monkeys before, during, and after prolonged treatment with estradiol monobenzoate (E2B, 50 μg/kg body weight/day subcutaneously). A significant increase over pretreatment (p < 0.01) plasma TT3, TT4, and TBG was recorded on day 6 of E2B therapy. A further significant stepwise increase in these parameters was noted up to day 19 of E2B, when the levels plateaued for the rest of the period of E2B treatment. Two weeks after discontinuation of E2B, plasma TT3, TT4, and TBG had returned to the pretreatment range and remained so up to 40 days of observation. Although the percent free T3 and percent free T4 were significantly decreased (p < 0.01) during E2B therapy, the absolute concentrations of free T3 and free T4 were not altered. After prolonged E2B treatment the metabolic clearance rate, distribution space, and production rate (PR) of both T3 and T4 were decreased (p < 0.01). The extrathyroidal T4 pool (ETT4P) was significantly increased (p < 0.01), whereas ETT3P did not show any significant alterations (p > 0.05). The decreased PR of T4 might have been due to a direct inhibitory effect of E2B on the thyroid, whereas the decrease in PR of T3 might have been due to either decreased conversion of T4 to T3, to decreased secretion by the thyroid, or both.
Zebrafish as a model to study peripheral thyroid hormone metabolism in vertebrate development

Marjolein Heijlen, Anne M. Houbrechts, Veerle M. Darras
Gen Compar Endocr 1 Jul 2013; 188: 289-296

To unravel the role of thyroid hormones (THs) in vertebrate development it is important to have suitable animal models to study the mechanisms regulating TH availability and activity. Zebrafish (Danio rerio), with its rapidly and externally developing transparent embryo has been a widely used model in developmental biology for some time. To date many of the components of the zebrafish thyroid axis have been identified, including the TH transporters MCT8, MCT10 and OATP1C1, the deiodinases D1, D2 and D3, and the receptors TRα and TRβ. Their structure and function closely resemble those of higher vertebrates. Interestingly, due to a whole genome duplication in the early evolution of ray-finned fishes, zebrafish possess two genes for D3 (dio3 and dio3a) and for TRα (thraa and thrab). Transcripts of all identified genes are present during embryonic development and several of them show dynamic spatio-temporal distribution patterns. Transient morpholino-knockdown of D2, D3 or MCT8 expression clearly disturbs embryonic development, confirming the importance of each of these regulators during early life stages. The recently available tools for targeted stable gene knockout will further increase the value of zebrafish to study the role of peripheral TH metabolism in pre- and post-hatch/post-natal vertebrate development.

The consequences of inappropriate treatment because of failure to recognize the syndrome of pituitary and peripheral tissue resistance to thyroid hormone

Samuel Refetoff, Angel Salazar, Terry J. Smith, Neal H. Scherberg
Metabolism  Aug 1983; 32(8); 822-834

Since the description of the syndrome of global (peripheral tissues and pituitary) resistance to thyroid hormone, new cases are being recognized with increasing frequency. The patient described herein had a markedly elevated serum TSH concentration of 260 μU/mL at the time of diagnosis. Studies suggest that elevations of serum TSH levels in this and other patients with the syndrome are most likely iatrogenic in origin. The patient was 312 years old when a goiter and a high serum T4 concentration were detected. Despite subtotal thyroidectomy, antithyroid drugs were required to maintain her T4 level in the normal range. She was referred at age 1112 years because of recurrent goiter. Her parents and five older siblings had normal thyroid function. Off therapy, her serum T4 level was 14.9 μg/dL, FT4I was 17.0, T3 was 362 ng/dL, TSH was 260 μU/mL, and antibodies were negative. There were no signs of thyrotoxicosis, her bone age was 7 years, her growth was stunted (third percentile), her intellectual quotient (IQ) was 67, and there was a 30–50 dB sensorineural hearing loss. The presence of a pituitary adenoma was ruled out. Her TSH had normal bioreactivity and rose to 540 μU/mL in response to TRH. Triiodothyronine was given in incremental doses of 50, 100, 200, and 400 μg/d over 28 days. The log concentrations of serum TSH showed an inverse linear correlation with serum T3. While receiving the highest dose of T3, on which the level of serum T3 ranged from 1400 to 2500 ng/dL, the TSH response to TRH normalized (basal 4.2 and peak 20 μU/mL), as did the high levels of serum cholesterol, carotene, and T4. Her BMR rose from +5 to +22%, her IQ rose to 77, and she gained weight without an increase in caloric intake. Only minimal changes were observed in levels of urinary cAMP, hydroxyproline, magnesium, and nitrogen. All values, with the exception of the weight gain, returned to baseline 2 months after T3 treatment was discontinued. The TSH level was suppressed by l-dopa and by prednisone. Long-term therapy with equivalent doses of T4 (from 300 to 1000 μg/d) produced a growth of 3 cm during the initial 6 weeks, 10.5 cm over the ensuring year (above the 10th percentile), and regression of goiter without thyrotoxicosis. The patient exhibited resistance to thyroid hormone in pituitary and peripheral tissues. The optimal dose of T4 replacement could be predicted by studying tissue responses to incremental doses of T3. The marked elevation in serum TSH concentration, stunted growth, and laboratory evidence of hypothyroidism were due to the limited thyroidal reserve caused by thyroidectomy. All patients with an impaired ability to compensate for the defect as a result of inappropriate treatment should be given thyroid hormone in amounts short of producing catabolic effects. Such a dose is expected to normalize the basal serum TSH concentration and its response to TRH.

Solving the mystery of iodine uptake

Valda Vinson
Science 20 Jun 2014; 344(6190), p. 1355
http://dx.doi.org:/10.1126/science.344.6190.1355-a

The thyroid gland produces iodine-containing hormones that regulate metabolism. The cell membrane protein NIS (sodium/iodine symporter) transports iodine into thyroid cells, but because iodine concentrations outside of the cell are so low, how it does so is a mystery. The key? Moving two sodium ions along with the iodine ion, Nicola et al found. NIS also does not bind sodium very tightly, but the high concentrations of sodium outside the cell allow one sodium ion to bind. This binding increases the affinity of NIS for a second sodium ion and also for iodine. With the three ions bound, NIS changes its conformation so that it opens to the inside of the cell, where the sodium concentration is low enough for NIS to release its sodium ions. When the sodium goes away, so does NIS’s affinity for iodine, leading NIS to release it.

Unliganded Thyroid Hormone Receptor α Regulates Developmental Timing via Gene Repression in Xenopus tropicalis

Jinyoung Choi, Ken-ichi T. Suzuki, Tetsushi Sakuma, Leena Shewade, Takashi Yamamoto, and Daniel R. Buchholz
Endocr Feb 2015; 156(2): 735–744 http://dx.doi.org:/10.1210/en.2014-1554

Thyroid hormone (TH) receptor (TR) expression begins early in development in all vertebrates when circulating TH levels are absent or minimal, yet few developmental roles for unliganded TRs have been established. Unliganded TRs are expected to repress TH-response genes, increase tissue responsivity to TH, and regulate the timing of developmental events. Here we examined the role of unliganded TRα in gene repression and development in Xenopus tropicalis. We used transcription activator-like effector nuclease gene disruption technology to generate founder animals with mutations in the TRα gene and bred them to produce F1 offspring with a normal phenotype and a mutant phenotype, characterized by precocious hind limb development. Offspring with a normal phenotype had zero or one disrupted TRα alleles , and tadpoles with the mutant hind limb phenotype had two truncated TRα alleles with frame shift mutations between the two zinc fingers followed by 40–50 mutant amino acids and then an out-of-frame stop codon. We examined TH-response gene expression and early larval development with and without exogenous TH in F1 offspring. As hypothesized, mutant phenotype tadpoles had increased expression of TH-response genes in the absence of TH and impaired induction of these same genes after exogenous TH treatment, compared with normal phenotype animals. Also, mutant hind limb phenotype animals had reduced hind limb and gill responsivity to exogenous TH. Similar results in methimazole-treated tadpoles showed that increased TH-response gene expression and precocious development were not due to early production of TH. These results indicate that unliganded TRα delays developmental progression by repressing TH-response genes.
The discovery of thyroid replacement therapy. Part 2: The critical 19th century
Conceptualizing the link between the thyroid and myxoedema

Stefan Slater
R Soc Med 2011; 104: 59–63. http://dx.doi.org:/10.1258/jrsm.2010.10k051

Sir William Withey Gull (1816–1890)

Frederik Ruysch, anatomist in Leyden around 1690, adopted, according to Albrecht von Haller in 1766, the opinion that a peculiar fluid was elaborated in the gland and poured into the veins’. The 19th century thus began with thyroidology at best in embryo; but during that century endocrinology was born and the thyroid was its standard bearer. In 1836, Thomas Wilkinson King of Guys Hospital, regarded by some as the ‘Father of Endocrinology’, anticipated on the basis of observation and experiment the internal secretion of the thyroid. In a meticulous paper on its anatomy: he wrote of the thyroid gland that ‘its absorbent vessels carry its peculiar secretion to the great veins of the body’. This language is almost identical to that of Ruysch and Haller more than a century earlier. The idea was prompted by the thyroid’s disproportionately large vascular supply in the absence of any evident mechanical or other local function and also at what he described as its ‘peculiar’ fluid. King notes that his view ‘has been indirectly surmised by Morgagni [probably in 1761] and others’.
In 1850, at a meeting of the Royal Medical and Chirurgical Society of London, chaired by Thomas Addison, Thomas Blizzard Curling, surgeon at the London Hospital, provided a clear clinicopathological correlate in a paper entitled ‘Two cases of absence of the thyroid body and symmetrical swellings of fat tissue at the sides of the neck, connected with defective cerebral development’.  Postmortem examination in each revealed no trace of thyroid tissue and that the swellings consisted only of fat.  Curling’s important observation was not pursued until 1871 when, at another meeting of the Society, Curling himself then in the chair, Charles Hilton Fagge, a physician at Guy’s Hospital, presented a paper on sporadic cretinism. He described four living cases and noted that none of them had a goiter and that one had been well up to the age of eight and, although now physically cretinous at age 16, she remained very intelligent. He referred to Curling’s paper and reached the same conclusion that the ‘healthy thyroid body is capable of exerting a counteracting influence [on cretinism]’.
Two years later, in 1873, Fagge’s senior colleague at Guy’s, Sir William Withey Gull, presented before the Clinical Society of London two of the five cases he had seen of what he called ‘A Cretinoid State supervening in Adult Life in Women’. He described their cretin-like appearance, drawing particular attention to the broad and thick tongue and the guttural voice and its pronunciation ‘as if the tongue were too large for the mouth’. He acknowledged his remarks were tentative, hence, he said, his use of the word ‘cretinoid’, but he had no doubt this was a ‘substantive’ condition and not one of cardiac or renal origin.
Gull was an interesting personality with apparently a remarkable presence, resembling Napoleon in face, form and manner (Figure). In the 1970s, 80 years after his death in 1890, he was the subject of a theory, quickly discredited, that he had been ‘Jack the Ripper’, the killer in the still unsolved murders and mutilations of at least five Whitechapel prostitutes in 1888. He figured in the 1988 TV film series, Jack the Ripper, starring Michael Caine as the detective. Gull is credited with the first description of hypothyroidism in adults and his paper was important in defining a recognizable clinical syndrome.
Then, in 1877, William Miller Ord, read his paper before the Royal Medical and Chirurgical Society of London and proposed the term ‘myxoedema’ for the adult condition. He described the non-pitting, ‘mucous edema’.   He also presented an engaging theory to explain the lethargy, inertia and slow responses associated with the disease. He suggested that these might result from the sheathing and insulation of the body in a ‘jelly-like’, mucin-laden integument that interfered with sensory perceptions and stimulation. Six years later, he chaired the committee set up by the Clinical Society of London to investigate the whole matter. He also later undertook some of the earliest metabolic studies of the effects of treating myxoedema with thyroid extract, showing the rapid weight loss and rise in temperature and in urinary volume and nitrogen excretion that occurred.
The key papers, which advanced these English authors observations, were those of the Swiss surgeons, Jaques-Louis Reverdin in Geneva and Emil Theodor Kocher in Bern, Kocher later receiving the Nobel Prize for his work on the thyroid. How fitting it is that it should be two Swiss doctors whose practices unlocked an understanding of the importance of the thyroid. For they each identified the late effects of total ablation (extirpation) of goiters. they

noted the great similarity of Gull’s and Ord’s myxoedema cases with their affected postoperative patients, referring to the comparison as a ‘rapprochement complet’, clearly making the connection. They acknowledged Gull’s primacy in describing the clinical manifestations and Ord’s ‘christening’ the condition ‘myxoedema’, and proposed that surgical cases be known as ‘myxoedème opératoire’. In light of his findings in 1882, Reverdin thereafter sought to conserve a part of the gland during thyroidectomy for goiter, speculating that its complete removal may have been responsible for these late effects. He had noticed that no such problems followed a just unilateral lobectomy. Kocher called the disease picture in his affected cases ‘cachexia strumipriva’ – literally, a bad condition due to the removal of a struma (goiter) without reference to the earlier work of Reverdin. Halsted noted in his monumental review of goiter surgery: ‘It is interesting to follow the argumentation of a mind so exceptionally keen and sane as Kocher’s in its futile efforts to explain insufficiently illuminated phenomena’. In reading Kocher’s 1909 Nobel Prize Lecture (in English translation), one gets the impression that Kocher was aware in 1883 of Gull’s and Ord’s reports, despite not referring to them, and he dismisses Reverdin’s contribution.
There ensued a competition over the contribution to the thyroid discovery.  When post-thyroidectomy myxedema wsas brought to the attention of Kocher, he agreed it was analogous to his cases of cachexia strumipriva. It is also obvious that Kocher, like many surgeons of the time, cannot have engaged in routine postoperative outpatient follow-up, for otherwise the ensuing problems in his goiter-operated patients would have been detected years earlier. In respect of this key moment in the history of the thyroid, Reverdin could be said to hold the intellectual property. The thought has been expressed that perhaps he should have shared the 1909 Nobel Prize with Kocher.
The Emerging Roles of Thyroglobulin

Yuqian Luo, Yuko Ishido, Naoki Hiroi, Norihisa Ishii, and Koichi Suzuki
Adv in Endocr 2014, Article ID 189194, 7 pp http://dx.doi.org/10.1155/2014/189194

Thyroglobulin (Tg), the most important and abundant protein in thyroid follicles, is well known for its essential role in thyroid hormone synthesis. In addition to its conventional role as the precursor of thyroid hormones, we have uncovered a novel function of Tg as an endogenous regulator of follicular function over the past decade. The newly discovered negative feedback effect of Tg on follicular function observed in the rat and human thyroid provides an alternative explanation for the observation of follicle heterogeneity. Given the essential role of the regulatory effects of Tg, we consider that dysregulation of normal Tg function is associated with multiple human thyroid diseases including autoimmune thyroid disease and thyroid cancer. Additionally, extrathyroid Tg may serve a regulatory function in other organs. Further exploration of Tg action, especially at the molecular level, is needed to obtain a better understanding of both the physiological and pathological roles of Tg.

The Surgical Management of Thyroid Cancer

Sara A. Morrison, Hyunsuk Suh, and Richard A. Hodin
Rambam Maimonides Med J 2014; 5(2):e0008. http://dx.doi.org:/10.5041/RMMJ.10142

There are approximately 63,000 reported cases of thyroid carcinoma annually in the United States, representing roughly 4% of all documented malignancies.1 Diagnosis typically stems from work-up of a thyroid nodule. Data from the Framingham study suggests that palpable thyroid nodules are present in 4% of the US population,2 but non-palpable nodules may exist in up to 67% of the population. Such nodules are often found incidentally secondary to the rising use of imaging modalities in medical settings. The large majority of thyroid nodules are benign, with an overall reported risk of malignancy from 5% to 15%.
Thyroid cancer has been increasing in incidence, with the number of reported cases in the US rising by 25% over the last 3 years. With growing technological advances in the field and improved contributions of diagnostics, surgical decision-making and operative planning have taken on new challenges. Herein, we review the current clinical practice recommendations and active areas of surgical controversy, reflective of the most recently published professional consensus guidelines and a systematic review of the literature.
The use of FNA in current clinical practice has resulted in post-surgical pathology findings of malignancy in over 50% of specimens.7 The Bethesda System for Reporting Thyroid Cytopathology (TBSRTC) was developed in order to allow pathologists among varying institutions to communicate results to clinical care-takers with widely under-stood descriptors. Results of FNA biopsies are broken down into the following categories with the corresponding risks of malignancy: non-diagnostic or unsatisfactory (1%–4%), benign (0%–3%), atypia of undetermined significance or follicular lesion of undetermined significance (AUS/FLUS; 5%–15%), follicular neoplasm or suspicious for a follicular neoplasm (FN/sFN; 15%–30%), suspicious for malignancy (60%–75%), and malignant (97%–99%).
Mutational Panels.
AsuragenmiR Inform (Austin, TX, USA) mutation analysis assay and Thyroid Cancer Mutation Panel by Quest Diagnostics (Madison, NJ, USA) are the two main commercially available mutational tests which test for known genetic alterations such as BRAF, RAS, RET/PTC, and PAX8/PPAR. These mutational panels are highly specific for malignancy; however, due to the low overall frequency of these mutations in thyroid cancers, negative results do not rule out cancer. Therefore, mutational panel tests are considered a “rule-in” test. If a preoperative mutational test is positive, the nodule should be considered malignant, and total thyroidectomy should be recommended.
Gene Expression Profiling.
The most widely known gene expression profiling test is Afirma Gene Expression Classifier (Veracyte, San Francisco, CA, USA), and, with its recent clinical validation by Alexander et al., Afirma is already being utilized in many clinical settings. The Afirma Gene Expression Classifier (GEC) is an RNA-based assay that utilizes FNA samples to evaluate 167 molecular genes associated with benign nodules based on their proprietary algorithm. Unlike the mutational panel testing, Afirma testing is considered a “rule-out” test since the test has a high negative predictive value in distinguishing benign nodules. However, a positive result reported as “suspicious” carries only 38% risk of malignancy.
In all, these molecular tests should be utilized judiciously and should be considered as a complementary diagnostic tool in the management of thyroid nodules. In the future, molecular testing could become more cost-effective and accurate as a diagnostic tool while providing prognostic and therapeutic information.
Papillary Thyroid Cancer.
Total thyroidectomy is the gold standard for patients with a preoperative diagnosis of papillary thyroid cancer when the nodule is greater than 1 cm in size. Completion thyroidectomy is indicated in patients who have undergone prior lobectomy and are found on final pathology to have papillary thyroid cancer that is larger than 1 cm. The completion thyroidectomy should generally be performed within 6 months of the original procedure in order to minimize the risk of lymph node metastasis.
Involvement of cervical lymph nodes in papillary thyroid cancer is frequent, reported to occur in up to 50% of patients. The role of neck dissection at the time of total thyroidectomy is somewhat controversial, however, since most of the nodal involvement is microscopic and does not affect overall survival. It is generally agreed upon that a therapeutic neck dissection should be pursued in the setting of well-differentiated thyroid cancer patients with clinically positive lymph nodes, whether in the central or lateral neck compartments. Prophylactic neck dissection is not done for follicular thyroid cancer, as the rates of lymph node metastasis are typically less than 10%.
Medullary thyroid cancer (MTC) comprises 4% of all thyroid malignancies. The majority of cases are sporadic in nature; approximately 20%–25% represent familiar/hereditary syndromes. Diagnosis is commonly made by FNA biopsy with specific staining for the presence of calcitonin in the tissue specimen. All patients with a diagnosis of medullary thyroid cancer must be evaluated for multiple endocrine neoplasia (MEN) 2 and be ruled out for the synchronous presence of pheochromocytoma prior to scheduling thyroid surgery.
Effects of Dose Level of Anti-thyroid Drug Carbimazole on Thermoregulation and Blood Constituents in Male Rabbits (Oryctolagus cuniculus)

Intisar H. Saeed, Abdalla M. Abdelatif and Mohamed E. Elnageeb
Adv in Research 2014; 2(3): 129-144. Article no. AIR.2014.002

Carbimazole (CBZ) is an anti-thyroid drug commonly used in the treatment of hyperthyroidism. The objective of this study was to evaluate the effects of dose level of CBZ on thermoregulation and blood constituents in mature male rabbits. Twenty animals were assigned to 4 groups (A, B, C, D) of 5 each. Group A served as control and treated animals in groups B,C,D, received daily orally CBZ doses of 10, 15 and 20 mg/animal for 3 weeks, respectively.
The values of rectal temperature (Tr,), respiration rate (RR) and heart rate (HR) decreased in treated rabbits and the mean values of HR decreased with increase in the dose level of CBZ. The packed cell volume (PCV),  Hb concentration and total leukocyte count (TLC) were lower in CBZ treated rabbits. Serum levels of total protein and globulins increased and serum albumin level decreased in treated groups of rabbits. Serum urea level was lower in CBZ treated groups and there was an increase in serum urea level with increase in CBZ dose level. Serum cholesterol level was higher in treated groups and there was an increase in serum cholesterol level with increase in CBZ dose level. Plasma glucose level decreased significantly in CBZ treated groups compared with the control and the mean values decreased with increase in the dose level of CBZ. The results indicate that the responses of basic physiological parameters were almost dose dependent in the range adopted in this study.
Phosphatase Inhibitor Calyculin A Activates TRPC2 Channels in Thyroid FRTL-5 Cells

Pramod Sukumaran, MY Asghar, C Löf, T Viitanen, and Kid Törnquist
Calcium Signaling Jun 2014; 1(2)  http://www.researchpub.org/journal/cs/cs.html

We have previously shown that rat thyroid FRTL-5 cells express a calcium entry pathway regulated by a phosphatase. The nature of the calcium entry pathway is presently unknown. We have also shown that FRTL-5 cells express only the TRPC2 channel of the TRPC family of cation channels. In the present investigation we show, using pharmacological inhibitors, the measurement of sodium and calcium entry, stable TRPC2 knock-down cells, and transfection with a non-conducting form of TRPC2, that the calcium entry pathway regulated by a phosphatase is, in fact, the TRPC2 channel. Our data thus point to a novel mechanism by which the TRPC2 channels can be regulated.

Thyroxine Uptake by Perfused Rat Liver
No Evidence for Facilitation by Five Different Thyroxine-binding Proteins

Carl M. Mendel and Richard A. Weisiger
J. Clin. Invest.  1990; 86: 1840-1847

For each of the five protein-hormone complexes studied, the rate of hepatic uptake of T4 (measured under conditions expected to result in dissociation-limited uptake) closely approximated the rate of spontaneous dissociation of the protein-hormone complex within the hepatic sinusoids. These findings indicate an absence of special cellular mechanisms that facilitate the hepatic uptake of T4 from its plasma binding proteins, and support the view that uptake occurs from the free T4 pool after spontaneous dissociation of T4 from its binding proteins.
Thyroxine Transport and Distribution in Nagase Analbuminemic Rats

Carl M. Mendel, RR Cavalieri, LA Gavin, T Pettersson, and M Inoue
J. Clin. Invest. 1989; 83: 143-148

The postulate that thyroxine (T4) in plasma enters tissues by protein-mediated transport or enhanced dissociation from plasma-binding proteins leads to the conclusion that almost all T4 uptake by tissues in the rat occurs via the pool of albumin bound T4 (Pardridge, W. M., B. N. Premachandra, and G. Fierer. 1985. Am. J. Physiol. 248:G545-G550).
To directly test this postulate, and to test more generally whether albumin might play a special role in T4 transport in the rat, we performed in vivo kinetics studies in six Nagase analbuminemic rats and in six control rats, all of whom had similar serum T4 concentrations and percent free T4 values.
Evaluation of the plasma disappearance curves of simultaneously injected 125I-T4 and I31I-albumin indicated that the flux of T4 from the extracellular compartment into the rapidly exchangeable intracellular compartment was similar in the analbuminemic rats (51±21 ng/min, mean±SD) and in the control rats (54±15 ng/min), as was the size of the rapidly exchangeable intracellular pool of T4 (1.13±0.53 vs. 1.22±036 Mg). This latter finding was confirmed by direct analysis of tissue samples (liver, kidney, and brain). We also performed in vitro kinetics studies using the isolated perfused rat liver. The single-pass fractional extraction by normal rat liver of T4 in pooled analbuminemic rat serum was indistinguishable from that of T4 in pooled control rat serum (10.9±3.3%, n = 3, vs. 11.4±3.4%). When > 98% of the albumin was removed from normal rat serum by chromatography with Affi-Gel blue, the single-pass fractional extraction of T4 (measured by a bolus injection method) did not change (16.3±2.1%, n = 5, vs. 15.2±2.5%). These data provide the first valid experimental test of the enhanced

dissociation hypothesis and indicate that there is no special, substantive role for albumin in T4 transport in the rat.
Influence of thyroid receptors on breast cancer cell proliferation

  1. Conde, R. Paniagua, J. Zamora, M. J. Blanquez, B. Fraile, A. Ruiz & M. I. Arenas
    Ann Oncol 2005; http://dx.doi.org:/10.1093/annonc/mdj040

Background: The involvement of thyroid hormones in the development and differentiation of normal breast tissue has been established. However, the association between breast cancer and these hormones is controversial. Therefore, the objective of the present study was to determine the protein expression pattern of thyroid hormone receptors in different human breast pathologies and to evaluate their possible relationship with cellular proliferation.
Patients and methods: The presence of thyroid hormone receptors was evaluated by immunohistochemistry and western blot analysis in 84 breast samples that included 12 cases of benign proliferative diseases, 20 carcinomas in situ and 52 infiltrative carcinomas.
Results: TR-α was detected in the nuclei of epithelial cells from normal breast ducts and acini, while in any pathological type this receptor was located in the cytoplasm. However, TR-b presented a nuclear location in benign proliferative diseases and carcinomas in situ and a cytoplasmatic location in normal breast and infiltrative carcinomas. The highest proliferation index was observed in carcinomas in situ, although in infiltrative carcinomas an inverse correlation between this index and the TR-α expression was encountered.
Conclusions: The results of this study reveal substantial changes in the expression profile of thyroid hormone.
Zebrafish as a model for monocarboxyl transporter 8-deficiency

GD Vatine, D Zada, T Lerer-Goldshtein, A Tovin, G Malkinson, K Yaniv and L Appelbaum
J Biol Chem Nov 2012; Manuscript M112.413831
http://dx.doi.org:/10.1074/jbc.M112.413831

Background: Mutations in the thyroid hormone transporter MCT8 are associated with psychomotor retardation AHDS.
Results: In zebrafish, as in humans, mct8 is expressed primarily in the nervous system. Elimination of MCT8 causes severe neural impairment.
Conclusion: MCT8 is a crucial regulator during zebrafish embryonic development. Significance: Establishment of the first vertebrate model for MCT8-deficiency, which exhibits a neurological phenotype.
Unusual Ratio between Free Thyroxine and Free Triiodothyronine in a Long-Lived Mole-Rat Species with Bimodal Ageing

Yoshiyuki Henning, Christiane Vole, Sabine Begall, Martin Bens, et al.
PlusOne Nov 2014; 9(11),e113698. http://dx.doi.org:/10.1371/journal.pone.0113698

Ansell’s mole-rats (Fukomys anselli) are subterranean, long-lived rodents, which live in eusocial families, where the maximum lifespan of breeders is twice as long as that of non-breeders. Their metabolic rate is significantly lower than expected based on allometry, and their retinae show a high density of S-cone opsins. Both features may indicate naturally low thyroid hormone levels.
In the present study, we sequenced several major components of the thyroid hormone pathways and analyzed free and total thyroxine and triiodothyronine in serum samples of breeding and non-breeding F. anselli to examine whether
a) their thyroid hormone system shows any peculiarities on the genetic level,
b) these animals have lower hormone levels compared to euthyroid rodents (rats and guinea pigs), and
c) reproductive status, lifespan and free hormone levels are correlated.
Genetic analyses confirmed that Ansell’s mole-rats have a conserved thyroid hormone system as known from other mammalian species. Interspecific comparisons revealed that free thyroxine levels of F. anselli were about ten times lower than of guinea pigs and rats, whereas the free triiodothyronine levels, the main biologically active form, did not differ significantly amongst species. The resulting fT4:fT3 ratio is unusual for a mammal and potentially represents a case of natural hypothyroxinemia.
Comparisons with total thyroxine levels suggest that mole-rats seem to possess two distinct mechanisms that work hand in hand to downregulate fT4 levels reliably. We could not find any correlation between free hormone levels and reproductive status, gender or weight. Free thyroxine may slightly increase with age, based on subsignificant evidence. Hence, thyroid hormones do not seem to explain the different ageing rates of breeders and nonbreeders. Further research is required to investigate the regulatory mechanisms responsible for the unusual proportion of free thyroxine and free triiodothyronine.
Transthyretin Regulates Thyroid Hormone Levels in the Choroid Plexus, But Not in  the Brain Parenchyma: Study in a Transthyretin-Null Mouse Model

JA Palha, R Fernandes, GM De Escobar, V Episkopou, M Gottesman, and MJ Saraiva
Endocr 2000; 141(9): 3267–3272.

Transthyretin (TTR) is the major T4-binding protein in rodents. Using a TTR-null mouse model we asked the following questions.
1) Do other T4 binding moieties replace TTR in the cerebrospinal fluid (CSF)?
2) Are the low whole brain total T4 levels found in this mouse model associated with hypothyroidism, e.g. increased 59-deiodinase type 2 (D2) activity and RC3-neurogranin messenger RNA levels?
3) Which brain regions account for the decreased total whole brain T4 levels?
4) Are there changes in T3 levels in the brain?
Our results show the following.
1) No other T4-binding protein replaces TTR in the CSF of the TTR-null mice.
2) D2 activity is normal in the cortex, cerebellum, and hippocampus, and total brain RC3-neurogranin messenger RNA levels are not altered.
3) T4 levels measured in the cortex, cerebellum, and hippocampus are normal. However T4 and T3 levels in the choroid plexus are only 14% and 48% of the normal values, respectively.
4) T3 levels are normal in the brain parenchyma.
The data presented here suggest that TTR influences thyroid hormone levels in the choroid plexus, but not in the brain. Interference with the blood-choroid-plexus-CSF-TTR-mediated route of T4 entry into the brain caused by the absence of TTR does not produce measurable features of hypothyroidism. It thus appears that TTR is not required for T4 entry or for maintenance of the euthyroid state in the mouse brain.
Identification of monocarboxylate transporter 8 as a specific thyroid hormone transporter

E.C.H. Friesema, S Ganguly, A. Abdalla, J.E.M. Fox, AP. Halestrap, and TJ. Visser
J Biol Chem 2003; Manuscript M300909200
http://dx.doi.org/10.1074/jbc.M300909200

Transport of thyroid hormone across the cell membrane is required for its action and

metabolism. Recently, a T-type amino acid transporter was cloned which transports aromatic amino acids but not iodothyronines. This transporter belongs to the monocarboxylate transporter (MCT) family, and is most homologous with MCT8 (SLC16A2). Therefore, we cloned rat MCT8, and tested it for thyroid hormone transport in Xenopus laevis oocytes. Oocytes were injected with rat MCT8 cRNA, and after 3 days immunofluorescence microscopy demonstrated expression of the protein at the plasma membrane. MCT8 cRNA induced a ~10-fold increase in uptake of 10 nM 125I-labeled thyroxine (T4), 3,3′,5-triiodothyronine (T3), 3,3′,5′-triiodothyronine (rT3) and 3,3′-diiodothyronine. Due to the rapid uptake of the ligands, transport was only linear with time for <4 min. MCT8 did not transport Leu, Phe, Trp or Tyr. [125I]T4 transport was strongly inhibited by L-T4, D-T4, L-T3, D-T3, 3,3’,5-triiodothyroacetic acid, N-bromoacetyl-T3, and bromosulfophthalein. T3 transport was less affected by these inhibitors. Iodothyronine uptake in uninjected oocytes was reduced by albumin but the stimulation induced by MCT8 was markedly increased. Saturation analysis provided apparent Km values of 2-5 μM for T4, T3 and rT3. Immunohistochemistry showed high expression in liver, kidney, brain and heart. In conclusion, we have identified MCT8 as a very active and specific thyroid hormone transporter.
Thyroid hormones,T3 andT4, in the brain
Amy C. Schroeder and Martin L. Privalsky
Front Endocr Mar 2014; 5 article 40.  http://dx.doi.org:/10.3389/fendo.2014.00040

Thyroid hormones (THs) are essential for fetal and post-natal nervous system development and also play an important role in the maintenance of adult brain function. Of the two major THs, T4 (3,5,30,50-tetraiodo-l-thyronine) is classically viewed as an pro-hormone that must be converted toT3 (3,5,30-tri-iodo-l-thyronine) via tissue-level deiodinases for biological activity. THs primarily mediate their effects by binding to thyroid hormone receptor (TR) isoforms, predominantly TRα1 and TRβ1, which are expressed in different tissues and exhibit distinctive roles in endocrinology. Notably, the ability to respond toT4 and toT3 differs for the two TR isoforms, with TRα1 generally more responsive to T4 than TRβ1. TRα1 is also the most abundantly expressed TR isoform in the brain, encompassing 70–80% of all TR expression in this tissue. Conversion of T4 into T3 via deiodinase 2 in astrocytes has been classically viewed as critical for generating local T3 for neurons. However, deiodinase-deficient mice do not exhibit obvious defectives in brain development or function. Considering that TRα1 is well-established as the predominant isoform in brain, and that TRα1 responds to both T3 and T4, we suggest T4 may play a more active role in brain physiology than has been previously accepted.
Thyroid hormone action: astrocyte–neuron communication

Beatriz Morte and Juan Bernal
Front Endocr May 2014; 5, Article 82 http://dx.doi.org:/10.3389/fendo.2014.00082

Thyroid hormone (TH) action is exerted mainly through regulation of gene expression by binding of T3 to the nuclear receptors.T4 plays an important role as a source of intracellular T3 in the central nervous system via the action of the type 2 deiodinase (D2), expressed in the astrocytes. A model of T3 availability to neural cells has been proposed and validated. The model contemplates that brain T3 has a double origin: a fraction is available directly from the circulation, and another is produced locally from T4 in the astrocytes by D2. The fetal brain depends almost entirely on theT3 generated locally. The contribution of systemic T3 increases subsequently during development to account for approximately 50% of total brain T3 in the late postnatal and adult stages. In this article, we review the experimental data in support of this model, and how the factors affectingT3 availability in the brain, such as deiodinases and transporters, play a decisive role in modulating local TH action during development.
The Significance of Thyroid Hormone Transporters in the Brain

Juan Bernal
Endocr Apr 2005; 146(4):1698–1700. http://dx.doi.org:/10.1210/en.2005-0134

The MCT family comprises up to 14 members, some of which are involved in the transport of important substrates for the brain such as lactate and pyruvate. MCT8 has been shown to act as a specific transporter for T4 and T3 and displays slightly higher affinity for T3. Heuer et al. have also studied the regional expression of MCT8 mRNA. In addition to high expression levels in the choroid plexus, they found that MCT8 is expressed in neurons of the neocortex, hippocampus, basal ganglia, amygdala, hypothalamus, and the Purkinje cells of the cerebellum, all regions known to be sensitive to thyroid hormones. Expression of MCT8 in neurons suggests that neuronal uptake of the T3 produced in astrocytes is facilitated by this transporter.
The physiological significance ofMCT8 as a transporter for thyroid hormone is supported by the finding of mutations in humans by Dumitrescu et al. and Friesema et al.  The syndrome affects children from an early age and consists of severe developmental delay and neurological damage together with an unusually altered pattern of thyroid hormone levels in blood. The patients presented low total and free T4, high total and free T3, and low rT3. TSH was moderately elevated in two of the patients and normal or slightly elevated in the other five. Inactivating mutations of the MCT8 transporter could result in the altered thyroid hormone levels. In vitro uptake of T4 and T3 by fibroblasts isolated from affected males was strongly reduced, and intracellular D2 was increased 6- to 8-fold. It is thus hypothesized that the resulting increase in intracellularly generated T3 accumulates in blood because of its poor reuptake into cells.
The second trimester is also the period when thyroid hormone receptors increase in concentration in the brain. If MCT8 is needed at this stage of development for T3 entry into neurons, mutations of the transporter could interfere with T3-dependent developmental processes. Knowledge of the ontogenetic patterns of MCT8 in the human fetal brain would certainly be helpful. On the other hand, there is also the possibility that MCT8 mutations interfere with transport of other substrates for brain metabolism that could be even more important than T3 in determining the severity and outcome of the syndrome. Other members of the family transport metabolic substrates such as pyruvate and lactate, but MCT8 so far appears to be specific for iodothyronines

Peripheral markers of thyroid function: The effect of T4 monotherapy versus T4/T3 combination therapy in hypothyroid subjects: A randomized cross-over study

Ulla Schmidt, B Nygaard, EW Jensen, J Kvetny, A Jarløv, and Jens Faber
Endocrine Connections Jan 10, 2013 http://dx.doi.org:/10.1530/EC-12-0

Background: A recent randomized controlled trial suggests that hypothyroid subjects may find L-T4 and L-T3 combination therapy to be

superior to L-T4 monotherapy in terms of quality of life, suggesting that the brain registered increased T3 availability during the

combination therapy.

Hypothesis: Peripheral tissue might also be stimulated during T4/T3 combination therapy compared to T4 monotherapy.
Methods: Serum levels of Sex Hormone-Binding Globulin (SHBG), pro-collagen-1-N-terminal peptide (PINP), and N-terminal pro-brain natriuretic peptide (NT-proBNP) (representing hepatocyte, osteoblast, and cardiomyocyte stimulation, respectively) were measured in 26 hypothyroid subjects in a double blind, randomized, cross-over trial, which compared the replacement therapy with T4/T3 in combination (50 Fg T4 was substituted with 20 Fg T3) to T4 alone (once daily regimens). This was performed to obtain unaltered serum thyroid stimulating hormone (TSH) levels during the trial and between the two treatment groups. Blood sampling was performed 24 hours after the last intake of thyroid hormone medication.
Results: TSH remained unaltered between the groups ((median) 0.83 vs. 1.18 mU/l in T4/T3 combination and T4 mono-therapy, respectively; p=0.534). SHBG increased from (median) 75 nmol/l at baseline to 83 nmol/l in the T4/T3 group (p=0.015), but remained unaltered in the T4 group (67 nmol/l); thus, it was higher in the T4/T3 vs. T4 group (p=0.041). PINP levels were higher in the T4/T3 therapy (48 vs. 40 Fg/l (p<0.001)). NT-proBNP did not differ between the groups. Conclusions: T4/T3 combination therapy in hypothyroidism seems to have more metabolic effects than the T4 monotherapy.
Stimulatory effects of thyroid hormone on brain angiogenesis in vivo and in vitro

Liqun Zhang, CM Cooper-Kuhn, U Nannmark, K Blomgren and HG Kuhn
J Cereb Blood Flow & Metab 2010; 30:323–335. http://dx.doi.org:/10.1038/jcbfm.2009.216

Thyroid hormone is critical for the proper development of the central nervous system. However, the specific role of thyroid hormone on brain angiogenesis remains poorly understood. Treatment of rats from birth to postnatal day 21 (P21) with propylthiouracil (PTU), a reversible blocker of triiodothyronine (T3) synthesis, resulted in decreased brain angiogenesis, as indicated by reduced complexity and density of microvessels. However, when PTU was withdrawn at P22, these parameters were fully recovered by P90. These changes were paralleled by an  altered expression of vascular endothelial growth factor A (Vegfa) and basic fibroblast growth factor (Fgf2). Physiologic concentrations of T3 and thyroxine (T4) stimulated proliferation and tubulogenesis of rat brain derived endothelial (RBE4) cells in vitro. Protein and mRNA levels of VEGF-A and FGF-2 increased after T3 stimulation of RBE4 cells. The thyroid hormone receptor blocker NH-3 abolished T3-induced Fgf2 and Vegfα upregulation, indicating a receptor-mediated effect. Thyroid hormone inhibited the apoptosis in RBE4 cells and altered mRNA levels of apoptosis-related genes, namely Bcl2 and Bad. The present results show that thyroid hormone has a substantial impact on vasculature development in the brain. Pathologically altered vascularization could, therefore, be a contributing factor to the neurologic deficits induced by thyroid hormone deficiency.

Molecules important for thyroid hormone

synthesis and action – known facts and future perspectives

Klaudia Brix, Dagmar Führer, Heike Biebermann
Thyroid Research 2011, 4(Suppl 1):S9 http://www.thyroidresearchjournal.com/content/4/S1/S9

Thyroid hormones are of crucial importance for the functioning of nearly every organ. Remarkably, disturbances of thyroid hormone synthesis and function are among the most common endocrine disorders affecting approximately one third of the working German population. Over the last ten years our understanding of biosynthesis and functioning of these hormones has increased tremendously. This includes the identification of proteins involved in thyroid hormone biosynthesis like Thox2 and Dehal where mutations in these genes are responsible for certain degrees of hypothyroidism. One of the most important findings was the identification of a specific transporter for triiodothyronine (T3), the monocarboxylate transporter 8 (MCT8) responsible for directed transport of T3 into target cells and for export of thyroid hormones out of thyroid epithelial cells. Genetic disturbances of MCT8 in patients result in a biochemical constellation of high T3 levels in combination with low or normal TSH and thyroxine levels leading to a new syndrome of severe X-linked mental retardation. Importantly mice lacking MCT8 presented only with a mild phenotype, indicating that compensatory mechanisms exist in mice. Moreover, it has become clear that not only genomic actions of T3 exist. T3 is also capable to activate adhesion receptors and it signals via activation of PI3K and MAPK pathways. Most recently, thyroid hormone derivatives were identified, the thyronamines which are decarboxylated thyroid hormones initiating physiological actions like lowering body temperature and heart rate, thereby acting in opposite direction to the classical thyroid hormones. So far it is believed that thyronamines function via the activation of a G-protein coupled receptor, TAAR1. The objective of this review is to summarize the recent findings in thyroid hormone synthesis and action and to discuss their implications for diagnosis of thyroid disease and for treatment of patients.

Retinoic Acid Induces Expression of the Thyroid Hormone Transporter, Monocarboxylate Transporter 8 (Mct8)

T Kogai, Yan-Yun Liu, LL Richter, K Mody, H Kagechika, and GA Brent
J Biol Chem Jun 2010. Manuscript M110.123158
http://www.jbc.org/cgi/doi/10.1074/jbc.M110.123158

Retinoic acid (RA) and thyroid hormone are critical for differentiation and organogenesis in the embryo. The monocarboxylate transporter-8 (Mct8), expressed predominantly in brain and placenta, mediates thyroid hormone uptake from the circulation and is required for normal neural development. RA induces differentiation of F9 mouse teratocarcinoma cells towards neurons as well as extraembryonal endoderm. We hypothesized that Mct8 is functionally expressed in F9 cells and induced by RA.  All trans RA (tRA), and other RA receptor (RAR) agonists, dramatically (> 300-fold) induced Mct8. tRA treatment significantly increased uptake of triiodothyronine and thyroxine (4.1 fold and 4.3 fold, respectively), which was abolished by a selective Mct8 inhibitor, bromosulfophthalein. Sequence inspection of the Mct8 promoter region and
5′-rapid amplification of cDNA ends (5’-RACE) PCR analysis in F9 cells identified
11 transcription start sites and a proximal Sp1 site, but no TATA-box.  tRA significantly enhanced Mct8 promoter activity through a consensus RA responsive element located 6.6 kilobases upstream of the coding region. Chromatin immunoprecipitation assay demonstrated binding of RAR and retinoid-X receptor (RXR) to the RA response element. The promotion of thyroid hormone uptake through the transcriptional up-regulation of Mct8 by RAR is likely to be important for extraembryonic endoderm development and neural differentiation. This finding demonstrates crosstalk between RA signaling and thyroid hormone signaling in early development at the level of the thyroid hormone transporter.
Abnormal thyroid hormone metabolism in mice lacking the monocarboxylate transporter 8

Marija Trajkovic, Theo J. Visser, Jens Mittag, Sigrun Horn, et al.
J. Clin. Invest.  2007; 117:627–635. http://dx.doi.org:/10.1172/JCI28253

In humans, inactivating mutations in the gene of the thyroid hormone transporter monocarboxylate transporter 8 (MCT8; SLC16A2) lead to severe forms of psychomotor retardation combined with imbalanced thyroid hormone serum levels. The MCT8-null mice described here, however, developed without overt deficits but also exhibited distorted 3,5,3′-triiodothyronine (T3) and thyroxine (T4) serum levels, resulting in increased hepatic activity of type 1 deiodinase (D1). In the mutants’ brains, entry of T4 was not affected, but uptake of T3 was diminished. Moreover, the T4 and T3 content in the brain of MCT8-null mice was decreased, the activity of D2 was increased, and D3 activity was decreased, indicating the hypothyroid state of this tissue. In the CNS, analysis of T3 target genes revealed that in the mutants, the neuronal T3 uptake was impaired in an area-specific manner, with strongly elevated thyrotropin-releasing hormone transcript levels in the hypothalamic paraventricular nucleus and slightly decreased RC3 mRNA expression in striatal neurons; however, cerebellar Purkinje cells appeared unaffected, since they did not exhibit dendritic outgrowth defects and responded normally to T3 treatment in vitro.
In conclusion, the circulating thyroid hormone levels of MCT8-null mice closely resemble those of humans with MCT8 mutations, yet in the mice, CNS development is only partially affected.
3-Monoiodothyronamine: the rationale for its action as an endogenous adrenergic-blocking neuromodulator

HS Gompf, JH Greenberg, G Aston-Jones, A Ianculescu, TS Scanlan, and MB Dratman
Brain Res. 2010 Sep 10; 1351: 130–140. http://dx.doi.org:/10.1016/j.brainres.2010.06.067

The investigations reported here were designed to gain insights into the role of
3-monoiodothyronamine (T1AM) in the brain, where the amine was originally identified and characterized.
Extensive deiodinase studies indicated that T1AM was derived from the T4 metabolite, reverse triiodothyronine (revT3), while functional studies provided well-confirmed evidence that T1AM has strong adrenergic blocking effects. Because a state of adrenergic overactivity prevails when triiodothyronine (T3) concentrations becomes excessive, the possibility that T3’s metabolic partner, revT3, might give rise to an antagonist of those T3 actions was thought to be reasonable.
All T1AM studies thus far have required use of pharmacological doses.
Therefore we considered that choosing a physiological site of action was a priority and focused on the locus coeruleus (LC), the major noradrenergic control center in the brain. Site-directed injections of T1AM into the LC elicited a significant, dose-dependent neuronal firing rate change in a subset of adrenergic neurons with an EC50=2.7 μM, a dose well within the physiological range. Further evidence for its physiological actions came from autoradiographic images obtained following intravenous carrier-free 125I-labeled T1AM injection. These showed that the amine bound with high affinity to the LC and to other selected brain nuclei, each of which is both an LC target and a known T3 binding site. This new evidence points to a physiological role for T1AM as an endogenous adrenergic-blocking neuromodulator in the central noradrenergic system.

Thyroid hormones are transported through the blood-brain barrier

Thyroid hormones are transported through the blood-brain barrier

Thyroid hormones are transported through the blood-brain barrier (OATP) or the blood-CSF barrier (OATP and MCT8). In the astrocytes and tanycytes T4 is converted to T3 which then enters the neurons through MCT8. In the neurons both T4 and T3 are degraded by D3. T3 from the tanycytes may reach the portal vessels in the median eminence. Other transporters may be present on the astrocyte or tanycyte membranes. In most cases the transport could be bidirectional, although only one direction is shown.
Juan Bernal – Instituto de Investigaciones Biomedicas – 28029 Madrid, Spain

the interactions of maternal, placental and fetal thyroid

the interactions of maternal, placental and fetal thyroid

Old and new concepts of thyroid hormone action.

A: Old concept of thyroid hormone action. In former times it was assumed that thyroid hormones are able to pass the plasma membrane by passive transport. Once in the cytosol T4 is deiodinated to T3 which exerts genomic effects by binding to the thyroid hormone receptor (TR). After hetero-dimerization with other nuclear receptors like retinoic X receptor (RXR), transcriptional regulation is initiated resulting in activation or inactivation of target genes.
B: New concepts of thyroid hormone action. Thyroid hormones enter a target cell via specific transporters, e.g. T3 uses the monocarboxylate transporter MCT8 while T4 entry is mediated by Lat2 or Oatp14. Moreover, T3 can interact with avb3 integrins to induce ERK1/2 signalling. Cytosolic T3 exerts genomic effects but can additionally also act by non-genomic means after TR binding and activation of down-stream PI-3 kinase. Likewise, the naturally occurring iodothyronine T2 is believed to stimulate metabolic rates via mitochondrial pathways, thereby bypassing genomic regulation. Besides thyroid hormones, derivatives like the thyronamines T1AM or T0AM, modulate the action of T3, e.g. counter-acting its effects in certain target cells. Thyronamines (TAMs) bind to and activate G-protein coupled receptors (GPCRs) of the trace amine associated receptor (TAAR) family. So far, it is only known that TAAR1 is activated by TAMs and signals via adenylylcyclase (AC) activation with subsequent rise of cAMP levels. However other GPCRs are likely targets for thyroid hormone derivatives

Brix et al.: Molecules important for thyroid hormone synthesis and action – known facts and future perspectives. Thyroid Research 2011 4(Suppl 1):S9.
http://dx.doi.org:/10.1186/1756-6614-4-S1-S9

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Metformin, thyroid-pituitary axis, diabetes mellitus, and metabolism


Metformin, thyroid-pituitary axis, diabetes mellitus, and metabolism

Larry H, Bernstein, MD, FCAP, Author and Curator
and Aviva Lev-Ari, PhD, RN

https://pharmaceuticalintelligence.com/9/27/2014/Metformin,_thyroid-pituitary_ axis,_diabetes_mellitus,_and_metabolism

The following article is a review of the central relationship between the action of
metformin as a diabetic medication and its relationship to AMPK, the important and
essential regulator of glucose and lipid metabolism under normal activity, stress, with
its effects on skeletal muscle, the liver, the action of T3 and more.

We start with a case study and a publication in the J Can Med Assoc.  Then we shall look
into key literature on these metabolic relationships.

Part I.  Metformin , Diabetes Mellitus, and Thyroid Function

Hypothyroidism, Insulin resistance and Metformin
May 30, 2012   By Janie Bowthorpe
The following was written by a UK hypothyroid patient’s mother –
Sarah Wilson.

My daughter’s epilepsy is triggered by unstable blood sugars. And since taking
Metformin to control her blood sugar, she has significantly reduced the number of
seizures. I have been doing research and read numerous academic medical journals,
which got me thinking about natural thyroid hormone and Hypothyroidism. My hunch
was that when patients develop hypothyroid symptoms, they are actually becoming
insulin resistant (IR). There are many symptoms in common between women with
polycystic ovaries and hypothyroidism–the hair loss, the weight gain, etc.
(http://insulinhub.hubpages.com/hub/PCOS-and-Hypothyroidism).

A hypothyroid person’s body behaves as if it’s going into starvation mode and so, to
preserve resources and prolong life, the metabolism changes. If hypothyroid is prolonged
or pronounced, then perhaps, chemical preservation mode becomes permanent even
with the reintroduction of thyroid hormones. To get back to normal, they need
a “jump-start” reinitiate a higher rate of metabolism. The kick start is initiated through
AMPK, which is known as the “master metabolic regulating enzyme.”
(http://en.wikipedia.org/wiki/AMP-activated protein kinase).

Guess what? This is exactly what happens to Diabetes patients when Metformin is
introduced. http://en.wikipedia.org/wiki/Metformin
Suggested articles: http://www.springerlink.com/content/r81606gl3r603167/  and
http://onlinelibrary.wiley.com/doi/10.1111/j.1365-2265.2011.04029.x/pdf

Note the following comments/partial statements:
“Hypothyroidism is characterized by decreased insulin responsiveness”;
“the pivotal regulatory role of T3 in major metabolic pathways”.

The community knows that T3/NTH (natural thyroid hormone [Armour]) makes
hypothyroid patients feel better – but the medical establishment is averse to T3/NTH
(treating subclinical hypoT (T3/T4 euthyroid) with natural dessicated thyroid (NDT).
The medical establishment might find an alternative view about impaired metabolism
more if shown real proof that the old NDT **was/is** having the right result –i.e., the
T3 is jump-starting the metabolism by re-activating
 AMPK.

If NDT also can be used for hypothyroidism without the surmised “dangers” of NTH,
then they should consider it. [The reality in the choice is actually recombinant TH
(Synthroid)]. Metformin is cheap, stable and has very few serious side effects. I use the
car engine metaphor, and refer to glucose as our petrol, AMPK as the spark plug and
both T3 and Metformin as the ignition switches. Sometimes if you have flat batteries in
the car, it doesn’t matter how much you turn the ignition switch or pump the petrol
pedal, all it does is flatten the battery and flood the engine.

Dr. Skinner in the UK has been treating “pre-hypothyroidism” the way that some
doctors treat “pre-diabetes”. Those hypothyroid patients who get treated early
might not have had their AMPK pathways altered and the T4-T3 conversion still works.
There seems to be no reason why thyroid hormone replacement therapy shouldn’t
logically be given to ward off a greater problem down the line.

It’s my belief that there is clear and abundant academic evidence that the AMPK/
Metformin research should branch out to also look at thyroid disease.

Point – direct T3 is kicking the closed -down metabolic process back into life,
just like Metformin does for insulin resistance.
http://www.hotthyroidology.com/editorial_79.html
There is serotonin resistance! http://www.ncbi.nlm.nih.gov/pubmed/17250776

Metformin Linked to Risk of Low Levels of Thyroid Hormone

CMAJ (Canadian Medical Association Journal) 09/22/2014

Metformin, the drug commonly for treating type 2 diabetes,

  • is linked to an increased risk of low thyroid-stimulating hormone
    (TSH) levels
  • in patients with underactive thyroids (hypothyroidism),

according to a study in CMAJ (Canadian Medical Association Journal).

Metformin is used to lower blood glucose levels

  • by reducing glucose production in the liver.

previous studies have raised concerns that

  • metformin may lower thyroid-stimulating hormone levels.

Study characteristics:

  1. Retrospective  long-term
  2. 74 300 patient who received metformin and sulfonylurea
  3. 25-year study period.
  4. 5689 had treated hypothyroidism
  5. 59 937 had normal thyroid function.

Metformin and low levels of thyroid-stimulating hormone in
patients with type 2 diabetes mellitus

Jean-Pascal Fournier,  Hui Yin, Oriana Hoi Yun Yu, Laurent Azoulay  +
Centre for Clinical Epidemiology (Fournier, Yin, Yu, Azoulay), Lady Davis Institute,
Jewish General Hospital; Department of Epidemiology, Biostatistics and Occupational
Health (Fournier), McGill University; Division of Endocrinology (Yu), Jewish General
Hospital; Department of Oncology (Azoulay), McGill University, Montréal, Que., Cananda

CMAJ Sep 22, 2014,   http://dx.doi.org:/10.1503/cmaj.140688

Background:

  • metformin may lower thyroid-stimulating hormone (TSH) levels.

Objective:

  • determine whether the use of metformin monotherapy, when compared with
    sulfonylurea monotherapy,
  • is associated with an increased risk of low TSH levels(< 0.4 mIU/L)
  • in patients with type 2 diabetes mellitus.

Methods:

  • Used the Clinical Practice Research Datalink,
  • identified patients who began receiving metformin or sulfonylurea monotherapy
    between Jan. 1, 1988, and Dec. 31, 2012.
  • 2 subcohorts of patients with treated hypothyroidism or euthyroidism,

followed them until Mar. 31, 2013.

  • Used Cox proportional hazards models to evaluate the association of low TSH
    levels with metformin monotherapy, compared with sulfonylurea monotherapy,
    in each subcohort.

Results:

  • 5689 patients with treated hypothyroidism and 59 937 euthyroid patients were
    included in the subcohorts.

For patients with treated hypothyroidism:

  1. 495 events of low TSH levels were observed (incidence rate 0.1197/person-years).
  2. 322 events of low TSH levels were observed (incidence rate 0.0045/person-years)
    in the euthyroid group.
  • metformin monotherapy was associated with a 55% increased risk of low TSH
    levels 
    in patients with treated hypothyroidism (incidence rate 0.0795/person-years
    vs.0.1252/ person-years, adjusted hazard ratio [HR] 1.55, 95% confidence
    interval [CI] 1.09– 1.20), compared with sulfonylurea monotherapy,
  • the highest risk in the 90–180 days after initiation (adjusted HR 2.30, 95% CI
    1.00–5.29).
  • No association was observed in euthyroid patients (adjusted HR 0.97, 95% CI 0.69–1.36).

Interpretation: The clinical consequences of this needs further investigation.

 

Crude and adjusted hazard ratios for suppressed thyroid-stimulating hormone
levels (< 0.1 mIU/L) associated with the use metformin monotherapy, compared
with sulfonylurea monotherapy, in patients with treated hypothyroidism or
euthyroidism and type 2 diabetes
Variable No. events
suppressed
TSH levels
Person-years of
exposure
Incidence rate,
per 1000 person-years (95% CI)
Crude
HR
Adjusted HR*(95% CI)
Patients with treated hypothyroidism, = 5689
Sulfonylure,
= 762
18 503 35.8
(21.2–56.6)
1.00 1.00
(reference)
Metformin,
= 4927
130 3 633 35.8
(29.9–42.5)
1.05 0.99
(0.57–1.72)
Euthyroid patients, = 59 937
Sulfonylurea,
= 7980
12 8 576 1.4
(0.7–2.4)
1.00 1.00
(reference)
Metformin,
= 51 957
75 63 047 1.2
(0.9–1.5)
0.85 1.03
(0.52–2.03)

 

Part II. Metabolic Underpinning 
(Source: Wikipedia, AMPK and thyroid)

5′ AMP-activated protein kinase or AMPK or 5′ adenosine monophosphate-activated protein kinase
is an enzyme that plays a role in cellular energy homeostasis.
It consists of three proteins (subunits) that

  1. together make a functional enzyme, conserved from yeast to humans.
  2. It is expressed in a number of tissues, including the liver, brain, and skeletal
    muscle.
  3. The net effect of AMPK activation is stimulation of
    1. hepatic fatty acid oxidation and ketogenesis,
    2. inhibition of cholesterol synthesis,
    3. lipogenesis, and triglyceride synthesis,
    4. inhibition of adipocyte lipolysis and lipogenesis,
    5. stimulation of skeletal muscle fatty acid oxidation and muscle
      glucose uptake, and
    6. modulation of insulin secretion by pancreatic beta-cells.

The heterotrimeric protein AMPK is formed by α, β, and γ subunits. Each of these three
subunits takes on a specific role in both the stability and activity of AMPK.

  • the γ subunit includes four particular Cystathionine beta synthase (CBS) domains
    giving AMPK its ability to sensitively detect shifts in the AMP:ATP ratio.
  • The four CBS domains create two binding sites for AMP commonly referred to as
    Bateman domains. Binding of one AMP to a Bateman domain cooperatively
    increases the binding affinity of the second AMP to the other Bateman domain.
  • As AMP binds both Bateman domains the γ subunit undergoes a conformational
    change which exposes the catalytic domain found on the α subunit.
  • It is in this catalytic domain where AMPK becomes activated when
    phosphorylation takes place at threonine-172by an upstream AMPK kinase
    (AMPKK). The α, β, and γ subunits can also be found in different isoforms.

AMPK acts as a metabolic master switch regulating several intracellular systems

  1. the cellular uptake of glucose,
  2. the β-oxidation of fatty acids and
  3. the biogenesis of glucose transporter 4 (GLUT4) and
  4. mitochondria

The energy-sensing capability of AMPK can be attributed to

  • its ability to detect and react to fluctuations in the AMP:ATP ratio that take
    place during rest and exercise (muscle stimulation).

During muscle stimulation,

  • AMP increases while ATP decreases, which changes AMPK into a good substrate
    for activation.
  • AMPK activity increases while the muscle cell experiences metabolic stress
    brought about by an extreme cellular demand for ATP.
  • Upon activation, AMPK increases cellular energy levels by
    • inhibiting anabolic energy consuming pathways (fatty acid synthesis,
      protein synthesis, etc.) and
    • stimulating energy producing, catabolic pathways (fatty acid oxidation,
      glucose transport, etc.).

A recent JBC paper on mice at Johns Hopkins has shown that when the activity of brain
AMPK was pharmacologically inhibited,

  • the mice ate less and lost weight.

When AMPK activity was pharmacologically raised (AICAR see below)

  • the mice ate more and gained weight.

Research in Britain has shown that the appetite-stimulating hormone ghrelin also
affects AMPK levels.

The antidiabetic drug metformin (Glucophage) acts by stimulating AMPK, leading to

  1. reduced glucose production in the liver and
  2. reduced insulin resistance in the muscle.

(Metformin usually causes weight loss and reduced appetite, not weight gain and
increased appetite, ..opposite of expected from the Johns Hopkins mouse study results.)

Triggering the activation of AMPK can be carried out provided two conditions are met.

First, the γ subunit of AMPK

  • must undergo a conformational change so as to
  • expose the active site(Thr-172) on the α subunit.

The conformational change of the γ subunit of AMPK can be accomplished

  • under increased concentrations of AMP.

Increased concentrations of AMP will

  • give rise to the conformational change on the γ subunit of AMPK
  • as two AMP bind the two Bateman domains located on that subunit.
  • It is this conformational change brought about by increased concentrations
    of  AMP that exposes the active site (Thr-172) on the α subunit.

This critical role of AMP is further substantiated in experiments that demonstrate

  • AMPK activation via an AMP analogue 5-amino-4-imidazolecarboxamide
    ribotide (ZMP) which is derived fromthe familiar
  • 5-amino-4-imidazolecarboxamide riboside (AICAR)

AMPK is a good substrate for activation via an upstream kinase complex, AMPKK
AMPKK is a complex of three proteins,

  1. STE-related adaptor (STRAD),
  2. mouse protein 25 (MO25), and
  3. LKB1 (a serine/threonine kinase).

The second condition that must be met is

  • the phosphorylation/activation of AMPK on its activating loop at
    Thr-172of the α subunit
  • brought about by an upstream kinase (AMPKK).

The complex formed between LKB1 (STK 11), mouse protein 25 (MO25), and the
pseudokinase STE-related adaptor protein (STRAD) has been identified as

  • the major upstream kinase responsible for phosphorylation of AMPK
    on its activating loop at Thr-172

Although AMPK must be phosphorylated by the LKB1/MO25/STRAD complex,

  • it can also be regulated by allosteric modulators which
  • directly increase general AMPK activity and
  • modify AMPK to make it a better substrate for AMPKK
  • and a worse substrate for phosphatases.

It has recently been found that 3-phosphoglycerate (glycolysis intermediate)

  • acts to further pronounce AMPK activation via AMPKK

Muscle contraction is the main method carried out by the body that can provide
the conditions mentioned above needed for AMPK activation

  • As muscles contract, ATP is hydrolyzed, forming ADP.
  • ADP then helps to replenish cellular ATP by donating a phosphate group to
    another ADP,

    • forming an ATP and an AMP.
  • As more AMP is produced during muscle contraction,
    • the AMP:ATP ratio dramatically increases,
  • leading to the allosteric activation of AMPK

For over a decade it has been known that calmodulin-dependent protein kinase
kinase-beta (CaMKKbeta) can phosphorylate and thereby activate AMPK,

  • but it was not the main AMPKK in liver.

CaMKK inhibitors had no effect on 5-aminoimidazole-4-carboxamide-1-beta-4-
ribofuranoside (AICAR) phosphorylation and activation of AMPK.

  • AICAR is taken into the celland converted to ZMP,
  • an AMP analogthat has been shown to activate AMPK.

Recent LKB1 knockout studies have shown that without LKB1,

  • electrical and AICAR stimulation of muscleresults in very little
    phosphorylation of AMPK and of ACC, providing evidence that
  • LKB1-STRAD-MO25 is the major AMPKK in muscle.

Two particular adipokines, adiponectin and leptin, have even been demonstrated
to regulate AMPK. A main functions of leptin in skeletal muscle is

  • the upregulation of fatty acid oxidation.

Leptin works by way of the AMPK signaling pathway, and adiponectin also
stimulates the oxidation of fatty acids via the AMPK pathway, and

  • Adiponectin also stimulates the uptake of glucose in skeletal muscle.

An increase in enzymes which specialize in glucose uptake in cells such as GLUT4
and hexokinase II are thought to be mediated in part by AMPK when it is activated.
Increases in AMPK activity are brought about by increases in the AMP:ATP ratio
during single bouts of exercise and long-term training.

One of the key pathways in AMPK’s regulation of fatty acid oxidation is the

  • phosphorylation and inactivation of acetyl-CoA carboxylase.
  1. Acetyl-CoA carboxylase (ACC) converts acetyl-CoA (ACA) to malonyl-CoA
    (MCA), an inhibitor of carnitine palmitoyltransferase 1 (CPT-1).
  2. CPT-1 transports fatty acids into the mitochondria for oxidation.
  3. Inactivation of ACC results in increased fatty acid transport and oxidation.
  4. the AMPK induced ACC inactivation  and reduced conversion to MCA
    may occur as a result of malonyl-CoA decarboxylase (MCD)
  5. MCD as an antagonist to ACC, decarboxylatesmalonyl-CoA to acetyl-CoA
    (reversal of ACC conversion of ACA to MCA)
  6. This resultsin decreased malonyl-CoA and increased CPT-1 and fatty acid oxidation.

AMPK also plays an important role in lipid metabolism in the liver. It has long been
known that hepatic ACC has been regulated in the liver.

  1. It phosphorylates and inactivates 3-hydroxy-3-methylglutaryl-CoA reductase (HMGCR)
  2. acetyl-CoA(ACA) is converted to mevalonic acid (MVA) by ACC
    with inhibition of CPT-1
  3. HMGR converts 3-hydroxy-3-methylglutaryl-CoA, which is made from MVA
  4. which then travels down several more metabolic steps to become cholesterol.

Insulin facilitates the uptake of glucose into cells via increased expression and
translocation of glucose transporter GLUT-4. In addition, glucose is phosphorylated
by hexokinase wheni iot enters the cell. The phosphorylated form keeps glucose from
leaving the cell,

  • The decreasedthe concentration of glucose molecules creates a gradient for more
    glucose to be transported into the cell.
AMPK and thyroid hormone regulate some similar processes. Knowing these similarities,
Winder and Hardie et al. designed an experiment to see if AMPK was influenced by thyroid
hormone. They found that all of the subunits of AMPK were increased in skeletal muscle,
especially in the soleus and red quadriceps, with thyroid hormone treatment. There was
also an increase in phospho-ACC, a marker of AMPK activity.
  •  Winder WW, Hardie DG (July 1999). “AMP-activated protein kinase,
    a metabolic master switch: possible roles in type 2 diabetes”. J. Physiol. 277
    (1 Pt 1): E1–10. PMID 10409121.
  • Winder WW, Hardie DG (February 1996). “Inactivation of acetyl-CoA
    carboxylase and activation of AMP-activated protein kinase in muscle
    during exercise”. J. Physiol. 270 (2 Pt 1): E299–304. PMID 8779952.
  • Hutber CA, Hardie DG, Winder WW (February 1997). “Electrical stimulation
    inactivates muscle acetyl-CoA carboxylase and increases AMP-activated
    protein kinase”. Am. J. Physiol. 272 (2 Pt 1): E262–6. PMID 9124333
  • Durante PE, Mustard KJ, Park SH, Winder WW, Hardie DG (July 2002).
    “Effects of endurance training on activity and expression of AMP-activated
    protein kinase isoforms in rat muscles”. Am. J. Physiol. Endocrinol.
    Metab. 283 (1): E178–86. doi:10.1152/ajpendo.00404.2001. PMID 12067859
  • Corton JM, Gillespie JG, Hardie DG (April 1994). “Role of the AMP-activated
    protein kinase in the cellular stress response”. Curr. Biol. 4 (4):
    315–24. doi:10.1016/S0960-9822(00)00070-1. PMID 7922340
  • Winder WW (September 2001). “Energy-sensing and signaling by
    AMP-activated protein kinase in skeletal muscle”. J. Appl. Physiol. 91 (3):
    1017–28. PMID 11509493
  • Suter M, Riek U, Tuerk R, Schlattner U, Wallimann T, Neumann D (October
    2006). “Dissecting the role of 5′-AMP for allosteric stimulation, activation,
    and deactivation of AMP-activated protein kinase”.  J. Biol. Chem.
    281 (43): 32207–6. doi:10.1074/jbc.M606357200. PMID 16943194

 

Part III. Pituitary-thyroid axis and diabetes mellitus
The Interface Between Thyroid and Diabetes Mellitus

Leonidas H. Duntas, Jacques Orgiazzi, Georg Brabant   Clin Endocrinol. 2011;75(1):1-9.
Interaction of Metformin and Thyroid Function

Metformin acts primarily by

  • suppressing hepatic gluconeogenesis via activation of AMPK
  • It has the opposite effects on hypothalamic AMPK,
    • inhibiting activity of the enzyme.
  • the metformin effects on hypothalamic AMPK activity will
    • counteractT3 effects at the hypothalamic level.
  • AMPK therefore represents a direct target for dual regulation
    • in the hypothalamic partitioning of energy homeostasis.
  • metformin crossesthe blood–brain barrier and
    • levels in the pituitary gland are substantially increased.
  • It convincinglysuppresses TSH

A recent study recruiting 66 patients with benign thyroid nodules furthermore
demonstrated that metformin significantly decreases nodule size in patients with
insulin resistance.[76] The effect of metformin, which was produced over a
6-month treatment period, parallelled a fall in TSH concentrations and achieved a
shrinkage amounting to 30% of the initial nodule size when metformin was
administered alone and up to 55% when it was added to ongoing LT4 treatment.

These studies reveal a

  • suppressive effect of metformin on TSH secretion patterns in
    hypothyroid patients, an effect that is apparently
  • independent of T4 treatment and does not alter the TH profile.
  • A rebound of TSH secretion occurs at about 3 months following metformin
    withdrawal.

It appears that recommendations for more frequent testing, on an annual to
biannual basis, seems justified in higher risk groups like patients over 50 or 55,
particularly with suggestive symptoms, raised antibody titres or dylipidaemia.
We thus would support the suggestion of an initial TSH and TPO antibody testing
which, as discussed, will help to predict the development of hypothyroidism in
patients with diabetes.

Hypothalamic AMPK and fatty acid metabolism mediate thyroid
regulation of energy 
balance
M López,  L Varela,  MJ Vázquez,  S Rodríguez-Cuenca, CR González, …, & Vidal-Puig
Nature Medicine  29 Aug 2010; 16: 1001–1008 http://dx.doi.org:/10.1038/nm.2207

Thyroid hormones have widespread cellular effects; however it is unclear whether
their effects on the central nervous system (CNS) contribute to global energy balance.
Here we demonstrate that either

  • whole-body hyperthyroidism or central administration of triiodothyronine
    (T3) decreases

    • the activity of hypothalamic AMP-activated protein kinase (AMPK),
    • increases sympathetic nervous system (SNS) activity and
    • upregulates thermogenic markers in brown adipose tissue (BAT).

Inhibition of the lipogenic pathway in the ventromedial nucleus of the hypothalamus
(VMH) prevents CNS-mediated activation of BAT by thyroid hormone and reverses
the weight loss associated with hyperthyroidism. Similarly, inhibition of thyroid
hormone receptors in the VMH reverses the weight loss associated with hyperthyroidism.

This regulatory mechanism depends on AMPK inactivation, as genetic inhibition of this
enzyme in the VMH of euthyroid rats induces feeding-independent weight loss and
increases expression of thermogenic markers in BAT. These effects are reversed by
pharmacological blockade of the SNS. Thus, thyroid hormone–induced modulation
of AMPK activity and lipid metabolism in the hypothalamus is a major regulator of
whole-body energy homeostasis.

Metabolic Basis for Thyroid Hormone Liver Preconditioning:
Upregulation of AMP-Activated Protein Kinase Signaling
  
LA Videla,1 V Fernández, P Cornejo, and R Vargas
1Molecular and Clinical Pharmacology Program, Institute of Biomedical Sciences,
Faculty of Medicine, University of Chile, 2Faculty of Medicine, Diego Portales University,
Santiago, Chile
Academic Editors: H. M. Abu-Soud and D. Benke
The Scientific World Journal 2012; 2012, ID 475675, 10 pp
http://dx.doi.org/10.1100/2012/475675

The liver is a major organ responsible for most functions of cellular metabolism and

  • a mediator between dietary and endogenous sources of energy for extrahepatic tissues.
  • In this context, adenosine-monophosphate- (AMP-) activated protein kinase (AMPK)
    constitutes an intrahepatic energy sensor
  • regulating physiological energy dynamics by limiting anabolism and stimulating
    catabolism, thus increasing ATP availability.
  • This is achieved by mechanisms involving direct allosteric activation and
    reversible phosphorylation of AMPK, in response to signals such as

    • energy status,
    • serum insulin/glucagon ratio,
    • nutritional stresses,
    • pharmacological and natural compounds, and
    • oxidative stress status.

Reactive oxygen species (ROS) lead to cellular AMPK activation and

  • downstream signaling under several experimental conditions.

Thyroid hormone (L-3,3′,5-triiodothyronine, T3) administration, a condition
that enhances liver ROS generation,

  • triggers the redox upregulation of cytoprotective proteins
    • affording preconditioning against ischemia-reperfusion (IR) liver injury.

Data discussed in this work suggest that T3-induced liver activation of AMPK

  • may be of importance in the promotion of metabolic processes
  • favouring energy supply for the induction and operation of preconditioning
    mechanisms.

These include

  1. antioxidant,
  2. antiapoptotic, and
  3. anti-inflammatory mechanisms,
  4. repair or resynthesis of altered biomolecules,
  5. induction of the homeostatic acute-phase response, and
  6. stimulation of liver cell proliferation,

which are required to cope with the damaging processes set in by IR.

The liver functions as a mediator between dietary and endogenous sources
of energy and extrahepatic organs that continuously require energy, mainly
the brain and erythrocytes, under cycling conditions between fed and fasted states.

In the fed state, where insulin action predominates, digestion-derived glucose is
converted to pyruvate via glycolysis, which is oxidized to produce energy, whereas
fatty acid oxidation is suppressed. Excess glucose can be either stored as hepatic
glycogen or channelled into de novo lipogenesis.

In the fasted state, considerable liver fuel metabolism changes occur due to decreased
serum insulin/glucagon ratio, with higher glucose production as a consequence of
stimulated glycogenolysis and gluconeogenesis (from alanine, lactate, and glycerol).

Major enhancement in fatty acid oxidation also occurs to provide energy for liver
processes and ketogenesis to supply metabolic fuels for extrahepatic tissues. For these
reasons, the liver is considered as the metabolic processing organ of the body, and
alterations in liver functioning affect whole-body metabolism and energy homeostasis.

In this context, adenosine-monophosphate- (AMP-) activated protein kinase (AMPK)
is the downstream component of a protein kinase cascade acting as an

  • intracellular energy sensor regulating physiological energy dynamics by
  • limiting anabolic pathways, to prevent excessive adenosine triphosphate (ATP)
    utilization, and
  • by stimulating catabolic processes, to increase ATP production.

Thus, the understanding of the mechanisms by which liver AMPK coordinates hepatic
energy metabolism represents a crucial point of convergence of regulatory signals
monitoring systemic and cellular energy status

Liver AMPK: Structure and Regulation

AMPK, a serine/threonine kinase, is a heterotrimeric complex comprising

  1. a catalytic subunit α and
  2. two regulatory subunits β and γ .

The α subunit has a threonine residue (Thr172) within the activation loop of the kinase
domain, with the C-terminal region being required for association with β and γ subunits.
The β subunit associates with α and γ by means of its C-terminal region , whereas

  • the γ subunit has four cystathionine β-synthase (CBS) motifs, which
  • bind AMP or ATP in a competitive manner.

75675.fig.001 (not shown)

Figure 1: Regulation of AMP-activated protein kinase (AMPK) by
(A) direct allosteric activation and
(B) reversible phosphorylation and downstream responses maintaining
intracellular energy balance.

Regulation of liver AMPK activity involves both direct allosteric activation and
reversible phosphorylation. AMPK is allosterically activated by AMP through

  • binding to the regulatory subunit-γ, which induces a conformational change in
    the kinase domain of subunit α that protects AMPK from dephosphorylation
    of Thr172, probably by protein phosphatase-2C.

Activation of AMPK requires phosphorylation of Thr172 in its α subunit, which can be
attained by either

(i) tumor suppressor LKB1 kinase following enhancement in the AMP/ATP ratio, a
kinase that plays a crucial role in AMPK-dependent control of liver glucose and
lipid metabolism;

(ii) Ca2+-calmodulin-dependent protein kinase kinase-β (CaMKKβ) that
phosphorylates AMPK in an AMP-independent, Ca2+-dependent manner;

(iii) transforming growth-factor-β-activated kinase-1 (TAK1), an important
kinase in hepatic Toll-like receptor 4 signaling in response to lipopolysaccharide.

Among these kinases, the relevance of CaMKKβ and TAK1 in liver AMPK activation
remains to be established in metabolic stress conditions. Both allosteric and
phosphorylation mechanisms are able to elicit

  • over 1000-fold increase in AMPK activity, thus allowing
  • the liver to respond to small changes in energy status in a highly sensitive fashion.

In addition to rapid AMPK regulation through allosterism and reversible phosphorylation

  • long-term effects of AMPK activation induce changes in hepatic gene expression.

This was demonstrated for

(i) the transcription factor carbohydrate-response element-binding protein (ChREBP),

  • whose Ser568 phosphorylation by activated AMPK
  • blocks its DNA binding capacity and glucose-induced gene transcription
  • under hyperlipidemic conditions;(ii) liver sterol regulatory element-binding
    protein-1c (SREBP-1c), whose mRNA and protein expression and those of
    its target gene for fatty acid synthase (FAS)
  • are reduced by metformin-induced AMPK activation,
  • decreasing lipogenesis and increasing fatty acid oxidation due to
    malonyl-CoA depletion;

(iii) transcriptional coactivator transducer of regulated CREB activity-2 (TORC2),
a crucial component of the hepatic gluconeogenic program, was reported
to be phosphorylated by activated AMPK.

This modification leads to subsequent cytoplasmatic sequestration of TORC2 and
inhibition of gluconeogenic gene expression, a mechanism underlying

  • the plasma glucose-lowering effects of adiponectin and metformin
  • through AMPK activation by upstream LKB1.

Activation of AMPK in the liver is a key regulatory mechanism controlling glucose
and lipid metabolism,

  1. inhibiting anabolic processes, and
  2. enhancing catabolic pathways in response to different signals, including
    1. energy status,
    2. serum insulin/glucagon ratio,
    3. nutritional stresses,
    4. pharmacological and natural compounds, and
    5. oxidative stress status

Reactive Oxygen Species (ROS) and AMPK Activation

The high energy demands required to cope with all the metabolic functions
of the liver are met by

  • fatty acid oxidation under conditions of both normal blood glucose levels and
    hypoglycemia, whereas
  • glucose oxidation is favoured in hyperglycemic states, with consequent
    generation of ROS.

Under normal conditions, ROS occur at relatively low levels due to their fast processing
by antioxidant mechanisms, whereas at acute or prolonged high ROS levels, severe
oxidation of biomolecules and dysregulation of signal transduction and gene expression
is achieved, with consequent cell death through necrotic and/or apoptotic-signaling
pathways.

Thyroid Hormone (L-3,3′,5-Triiodothyronine, T3), Metabolic Regulation,
and ROS Production

T3 is important for the normal function of most mammalian tissues, with major actions
on O2 consumption and metabolic rate, thus

  • determining enhancement in fuel consumption for oxidation processes
  • and ATP repletion.

T3 acts predominantly through nuclear receptors (TR) α and β, forming

  • functional complexes with retinoic X receptor that
  • bind to thyroid hormone response elements (TRE) to activate gene expression.

T3 calorigenesis is primarily due to the

  • induction of enzymes related to mitochondrial electron transport and ATP
    synthesis, catabolism, and
  • some anabolic processes via upregulation of genomic mechanisms.

The net result of T3 action is the enhancement in the rate of O2 consumption of target
tissues such as liver, which may be effected by secondary processes induced by T3

(i) energy expenditure due to higher active cation transport,

(ii) energy loss due to futile cycles coupled to increase in catabolic and anabolic pathways, and

(iii) O2 equivalents used in hepatic ROS generation both in hepatocytes and Kupffer cells

In addition, T3-induced higher rates of mitochondrial oxidative phosphorylation are
likely to induce higher levels of ATP, which are partially balanced by intrinsic uncoupling
afforded by induction of uncoupling proteins by T3. In agreement with this view, the
cytosolic ATP/ADP ratio is decreased in hyperthyroid tissues, due to simultaneous
stimulation of ATP synthesis and consumption.

Regulation of fatty acid oxidation is mainly attained by carnitine palmitoyltransferase Iα (CPT-Iα),

  • catalyzing the transport of fatty acids from cytosol to mitochondria for β-oxidation,
    and acyl-CoA oxidase (ACO),
  • catalyzing the first rate-limiting reaction of peroxisomal β-oxidation, enzymes that are
    induced by both T3 and peroxisome proliferator-activated receptor α (PPAR-α).

Furthermore, PPAR-α-mediated upregulation of CPT-Iα mRNA is enhanced by PPAR-γ
coactivator 1α (PGC-1α), which in turn

  • augments T3 induction of CPT-Iα expression.

Interestingly, PGC-1α is induced by

  1. T3,
  2. AMPK activation, and
  3. ROS,

thus establishing potential links between

  • T3 action, ROS generation, and AMPK activation

with the onset of mitochondrial biogenesis and fatty acid β-oxidation.

Liver ROS generation leads to activation of the transcription factors

  1. nuclear factor-κB (NF-κB),
  2. activating protein 1 (AP-1), and
  3. signal transducer and activator of transcription 3 (STAT3)

at the Kupffer cell level, with upregulation of cytokine expression (TNF-α, IL-1, IL-6),
which upon interaction with specific receptors in hepatocytes trigger the expression of

  1. cytoprotective proteins (Figure 3(A)).

These responses and the promotion of hepatocyte and Kupffer-cell proliferation
represent hormetic effects reestablishing

  1. redox homeostasis,
  2. promoting cell survival, and
  3. protecting the liver against ischemia-reperfusion injury.

T3 liver preconditioning also involves the activation of the

  1. Nrf2-Keap1 defense pathway
  • upregulating antioxidant proteins,
  • phase-2 detoxifying enzymes, and
  • multidrug resistance proteins, members of the ATP binding cassette (ABC)
    superfamily of transporters (Figure 3(B))

In agreement with T3-induced liver preconditioning, T3 or L-thyroxin afford
preconditioning against IR injury in the heart, in association with

  • activation of protein kinase C and
  • attenuation of p38 and
  • c-Jun-N-terminal kinase activation ,

and in the kidney, in association with

  • heme oxygenase-1 upregulation.

475675.fig.002

http://www.hindawi.com/journals/tswj/2012/floats/475675/thumbnails/475675.fig.002_th.jpg

Figure 2: Calorigenic response of thyroid hormone (T3) and its relationship with O2
consumption, reactive oxygen species (ROS) generation, and antioxidant depletion in the liver.
Abbreviations: CYP2E1, cytochrome P450 isoform 2E1; GSH, reduced glutathione; QO2, rate
of O2 consumption; SOD, superoxide dismutase.

475675.fig.003

genomic signaling in T3 calorigenesis and ROS production 475675.fig.003

genomic signaling in T3 calorigenesis and ROS production 475675.fig.003

http://www.hindawi.com/journals/tswj/2012/floats/475675/thumbnails/475675.fig.003_th.jpg

Figure 3: Genomic signaling mechanisms in T3 calorigenesis and liver reactive oxygen
species (ROS) production leading to
(A) upregulation of cytokine expression in Kupffer cells and hepatocyte activation of genes
conferring cytoprotection,
(B) Nrf2 activation controling expression of antioxidant and detoxication proteins, and
(C) activation of the AMPK cascade regulating metabolic functions.

Abbreviations: AP-1, activating protein 1; ARE, antioxidant responsive element; CaMKKβ,
Ca2+-calmodulin-dependent kinase kinase-β; CBP, CREB binding protein; CRC, chromatin
remodelling complex; EH, epoxide hydrolase; HO-1, hemoxygenase-1; GC-Ligase,
glutamate cysteine ligase; GPx, glutathione peroxidase; G-S-T, glutathione-S-transferase;
HAT, histone acetyltransferase; HMT, histone arginine methyltransferase; IL1,
interleukin 1; iNOS, inducible nitric oxide synthase; LKB1, tumor suppressor LKB1 kinase;
MnSOD, manganese superoxide dismutase; MRPs, multidrug resistance proteins; NF-κB,
nuclear factor-κB; NQO1, NADPH-quinone oxidoreductase-1; NRF-1, nuclear respiratory
factor-1; Nrf2, nuclear receptor-E2-related factor 2; PCAF, p300/CBP-associated
factor; RXR, retinoic acid receptor; PGC-1, peroxisome proliferator-activated receptor-γ
coactivator-1; QO2, rate of O2 consumption; STAT3, signal transducer and activator
of transcription 3; TAK1, transforming-growth-factor-β-activated kinase-1; TNF-α, tumor
necrosis factor-α; TR, T 3 receptor; TRAP, T3-receptor-associated protein; TRE,  T3 responsive element; UCP, uncoupling proteins; (—), reported mechanisms;
(- - - -), proposed mechanisms.

 

T3 is a key metabolic regulator coordinating short-term and long-term energy needs,
with major actions on liver metabolism. These include promotion of

(i) gluconeogenesis and hepatic glucose production, and

(ii) fatty acid oxidation coupled to enhanced adipose tissue lipolysis, with

  • higher fatty acid flux to the liver and
  • consequent ROS production (Figure 2) and
  • redox upregulation of cytoprotective proteins

affording liver preconditioning (Figure 3).

Thyroid Hormone and AMPK Activation: Skeletal Muscle and Heart

In skeletal muscle, T3 increases the levels of numerous proteins involved in

  1. glucose uptake (GLUT4),
  2. glycolysis (enolase, pyruvate kinase, triose phosphate isomerase),
  3. fatty acid oxidation (carnitine palmitoyl transferase-1, mitochondrial thioesterase I),
    and uncoupling protein-3,

effects that are achieved through enhanced transcription of TRE-containing genes

Skeletal muscle AMPK activation is characterized by

(i) being a rapid and transient response,

(ii) upstream activation by Ca2+-induced mobilization and CaMKKβ activation,

(iii) upstream upregulation of LKB1 expression, which requires association with STRAD
and MO25 for optimal phosphorylation/activation of AMPK, and

(iv) stimulation of mitochondrial fatty acid β-oxidation.

T3-induced muscle AMPK activation was found to trigger two major downstream

signaling pathways, namely,

(i) peroxisome proliferator-activated receptor-γ coactivator-1α (PGC-1α) mRNA
expression and phosphorylation, a transcriptional regulator for genes related to

  • mitochondrial biogenesis,
  • fatty acid oxidation, and
  • gluconeogenesis and

(ii) cyclic AMP response element binding protein (CREB) phosphorylation, which

  • in turn induces PGC-1α expression in liver tissue, thus
  • reinforcing mechanism (i).

These data indicate that AMPK phosphorylation of PGC-1α initiates many of the
important gene regulatory functions of AMPK in skeletal muscle.

In heart, hyperthyroidism increased glycolysis and sarcolemmal GLUT4 levels by the
combined effects of AMPK activation and insulin stimulation, with concomitant increase
in fatty acid oxidation proportional to enhanced cardiac mass and contractile function.

Thyroid Hormone, AMPK Activation, and Liver Preconditioning

Recent studies by our group revealed that administration of a single dose of 0.1 mg T3/kg
to rats activates liver AMPK (Figure 4; unpublished work).

  1. enhancement in phosphorylated AMPK/nonphosphorylated AMPK ratios in T3-
    treated rats over control values thatis significant in the time period of 1 to 48
    hours after hormone treatment
  2. Administration of a substantially higher dose (0.4 mg T3/kg) resulted in
    decreased liver AMPK activation at 4 h to return to control values at 6 h
    after treatment

Activation of liver AMPK by T3 may be of relevance in terms of

  • promotion of fatty acid oxidation for ATP supply,
  • supporting hepatoprotection against IR injury (Figure 3(C)).

This proposal is based on the high energy demands underlying effective liver
preconditioning for full operation of hepatic

  • antioxidant, antiapoptotic, and anti-inflammatory mechanisms,
  • oxidized biomolecules repair or resynthesis,
  • induction of the homeostatic acute-phase response, and
  • promotion of hepatocyte and Kupffer cell proliferation,

mechanisms that are needed to cope with the damaging processes set in by IR.
T3 liver preconditioning , in addition to that afforded by

  • n-3 long-chain polyunsaturated fatty acids given alone or
  • combined with T3 at lower dosages, or
  • by iron supplementation,

constitutes protective strategies against hepatic IR injury.

Studies on the molecular mechanisms underlying T3-induced liver AMPK
activation (Figure 4) are currently under assessment in our laboratory.

References

Fernández and L. A. Videla, “Kupffer cell-dependent signaling in thyroid hormone
calorigenesis: possible applications for liver preconditioning,” Current Signal
Transduction Therapy 2009; 4(2): 144–151.

Viollet, B. Guigas, J. Leclerc et al., “AMP-activated protein kinase in the regulation
of  hepatic energy metabolism: from physiology to therapeutic perspectives,” Acta
Physiologica 2009; 196(1): 81–98.

Carling, “The AMP-activated protein kinase cascade – A unifying system
for energy control,” Trends in Biochemical Sciences, 2004;. 29(1): 18–24.

E. Kemp, D. Stapleton, D. J. Campbell et al., “AMP-activated protein kinase,
super 
metabolic regulator,” Biochemical Society Transactions 2003; 31(1):
162–168
.

G. Hardie, “AMP-activated protein kinase-an energy sensor that
regulates all ;aspects of cell function,” Genes and Development,
2011; 25(18): 1895–1908.

Woods, P. C. F. Cheung, F. C. Smith et al., “Characterization of AMP-activated
protein kinase βandγ subunits Assembly of the heterotrimeric complex in vitro,”
Journal of Biological Chemistry 1996;271(17): 10282–10290.

Xiao, R. Heath, P. Saiu et al., “Structural basis for AMP binding to mammalian AMP-
activated protein kinase,” Nature 2007; 449(7161): 496–500.

more…

Impact of Metformin and compound C on NIS expression and iodine uptake in vitro and in vivo: a role for CRE in AMPK modulation of thyroid function.
Abdulrahman RM1, Boon MRSips HCGuigas BRensen PCSmit JWHovens GC.
Author information 
Thyroid. 2014 Jan;24(1):78-87.  Epub 2013 Sep 25.  PMID: 23819433
http://dx.doi.org:/10.1089/thy.2013.0041.

Although adenosine monophosphate activated protein kinase (AMPK) plays a crucial role
in energy metabolism, a direct effect of AMPK modulation on thyroid function has only
recently been reported, and much of its function in the thyroid is currently unknown.

The aim of this study was

  1. to investigate the mechanism of AMPK modulation in iodide uptake.
  2. to investigate the potential of the AMPK inhibitor compound C as an enhancer of
    iodide uptake by thyrocytes.

Metformin reduced NIS promoter activity (0.6-fold of control), whereas compound C
stimulated its activity (3.4-fold) after 4 days. This largely coincides with

  • CRE activation (0.6- and 3.0-fold).

These experiments show that AMPK exerts its effects on iodide uptake, at least partly,
through the CRE element in the NIS promoter. Furthermore, we have used AMPK-alpha1
knockout mice to determine the long-term effects of AMPK inhibition without chemical compounds.
These mice have a less active thyroid, as shown by reduced colloid volume and reduced
responsiveness to thyrotropin.

NIS expression and iodine uptake in thyrocytes

  • can be modulated by metformin and compound C.

These compounds exert their effect by

  • modulation of AMPK, which, in turn, regulates
  • the activation of the CRE element in the NIS promoter.

Overall, this suggests that AMPK modulating compounds may be useful for the
enhancement of iodide uptake by thyrocytes, which could be useful for the
treatment of thyroid cancer patients with radioactive iodine.

AMPK: Master Metabolic Regulator

© 1996–2013 themedicalbiochemistrypage.org, LLC | info
@ themedicalbiochemistrypage.org

AMPK-activating drugs metformin or phenformin might provide protection against cancer 1741-7007-11-36-5

AMPK-activating drugs metformin or phenformin might provide protection against cancer 1741-7007-11-36-5

 

AMPK and AMPK-related kinase (ARK) family  1741-7007-11-36-4

AMPK and AMPK-related kinase (ARK) family 1741-7007-11-36-4

 

central role of AMPK in the regulation of metabolism

 

 

AMP-activated protein kinase (AMPK) was first discovered as an activity that

AMPK induces a cascade of events within cells in response to the ever changing energy
charge of the cell. The role of AMPK in regulating cellular energy charge places this
enzyme at a central control point in maintaining energy homeostasis.

More recent evidence has shown that AMPK activity can also be regulated by physiological stimuli, independent of the energy charge of the cell, including hormones and nutrients.

 

Once activated, AMPK-mediated phosphorylation events

These events are rapidly initiated and are referred to as

  • short-term regulatory processes.

The activation of AMPK also exerts

  • long-term effects at the level of both gene expression and protein synthesis.

Other important activities attributable to AMPK are

  1. regulation of insulin synthesis and
  2. secretion in pancreatic islet β-cells and
  3. modulation of hypothalamic functions involved in the regulation of satiety.

How these latter two functions impact obesity and diabetes will be discussed below.

Regulation of AMPK

In the presence of AMP the activity of AMPK is increased approximately 5-fold.
However, more importantly is the role of AMP in regulating the level of phosphorylation
of AMPK. An increased AMP to ATP ratio leads to a conformational change in the γ-subunit
leading to increased phosphorylation and decreased dephosphorylation of AMPK.

The phosphorylation of AMPK results in activation by at least 100-fold. AMPK is
phosphorylated by at least three different upstream AMPK kinases (AMPKKs).
Phosphorylation of AMPK occurs in the α subunit at threonine 172 (T172) which

  • lies in the activation loop.

One kinase activator of AMPK is

  • Ca2+-calmodulin-dependent kinase kinase β (CaMKKβ)
  • which phosphorylates and activates AMPK in response to increased calcium.

The distribution of CaMKKβ expression is primarily in the brain with detectable levels
also found in the testes, thymus, and T cells. As described for the Ca2+-mediated
regulation of glycogen metabolism,

  • increased release of intracellular stores of Ca2+ create a subsequent demand for
    ATP.

Activation of AMPK in response to Ca fluxes

  • provides a mechanism for cells to anticipate the increased demand for ATP.

Evidence has also demonstrated that the serine-threonine kinase, LKB1 (also called
serine-threonine kinase 11, STK11) which is encoded by the Peutz-Jeghers syndrome
tumor suppressor gene, is required for activation of AMPK in response to stress.

The active LKB1 kinase is actually a complex of three proteins:

  1. LKB1,
  2. Ste20-related adaptor (STRAD) and
  3. mouse protein 25 (MO25).

Thus, the enzyme complex is often referred to as LKB1-STRAD-MO25. Phosphorylation
of AMPK by LKB1 also occurs on T172. Unlike the limited distribution of CaMKKβ,

  • LKB1 is widely expressed, thus making it the primary AMPK-regulating kinase.

Loss of LKB1 activity in adult mouse liver leads to

  • near complete loss of AMPK activity and
  • is associated with hyperglycemia.

The hyperglycemia is, in part, due to an increase in the transcription of gluconeogenic
genes. Of particular significance is the increased expression of

  • the peroxisome proliferator-activated receptor-γ (PPAR-γ) coactivator 1α
    (PGC-1α), which drives gluconeogenesis.
  • Reduction in PGC-1α activity results in normalized blood glucose levels in
    LKB1-deficient mice.

The third AMPK phosphorylating kinase is transforming growth factor-β-activated
kinase 1 (TAK1). However, the normal physiological conditions under which TAK1
phosphorylates AMPK are currently unclear.

The effects of AMP are two-fold:

  1. a direct allosteric activation and making AMPK a poorer substrate for
    dephosphorylation.

Because AMP affects both
the rate of AMPK phoshorylation in the positive direction and
dephosphorylation in the negative direction,

the cascade is ultrasensitive. This means that

  1. a very small rise in AMP levels can induce a dramatic increase in the activity of
    AMPK.

The activity of adenylate kinase, catalyzing the reaction shown below, ensures that

  • AMPK is highly sensitive to small changes in the intracellular [ATP]/[ADP] ratio.

2 ADP ——> ATP + AMP

Negative allosteric regulation of AMPK also occurs and this effect is exerted by
phosphocreatine. As indicated above, the β subunits of AMPK have a glycogen-binding domain, GBD. In muscle, a high glycogen content

  • represses AMPK activity and
  • this is likely the result of interaction between the GBD and glycogen,
  • the GBD of AMPK allows association of the enzyme with the regulation of glycogen metabolism
  • by placing AMPK in close proximity to one of its substrates glycogen synthase.

AMPK has also been shown to be activated by receptors that are coupled to

  • phospholipase C-β (PLC-β) and by
  • hormones secreted by adipose tissue (termed adipokines) such as leptinand adiponectin (discussed below).

Targets of AMPK

The signaling cascades initiated by the activation of AMPK exert effects on

  • glucose and lipid metabolism,
  • gene expression and
  • protein synthesis.

These effects are most important for regulating metabolic events in the liver, skeletal
muscle, heart, adipose tissue, and pancreas.

Demonstration of the central role of AMPK in the regulation of metabolism in response
to events such as nutrient- or exercise-induced stress. Several of the known physiologic
targets for AMPK are included as well as several pathways whose flux is affected by
AMPK activation. Arrows indicate positive effects of AMPK, whereas, T-lines indicate
the resultant inhibitory effects of AMPK action.

The uptake, by skeletal muscle, accounts for >70% of the glucose removal from the
serum in humans. Therefore, it should be obvious that this event is extremely important
for overall glucose homeostasis, keeping in mind, of course, that glucose uptake by
cardiac muscle and adipocytes cannot be excluded from consideration. An important fact
related to skeletal muscle glucose uptake is that this process is markedly impaired in
individuals with type 2 diabetes.

The uptake of glucose increases dramatically in response to stress (such as ischemia) and
exercise and is stimulated by insulin-induced recruitment of glucose transporters
to the plasma membrane, primarily GLUT4. Insulin-independent recruitment of glucose
transporters also occurs in skeletal muscle in response to contraction (exercise).

The activation of AMPK plays an important, albeit not an exclusive, role in the induction of
GLUT4 recruitment to the plasma membrane. The ability of AMPK to stimulate
GLUT4 translocation to the plasma membrane in skeletal muscle is by a different mechanism
than that stimulated by insulin and insulin and AMPK effects are additive.

Under ischemic/hypoxic conditions in the heart the activation of AMPK leads to the
phosphorylation and activation of the kinase activity of phosphofructokinase-2, PFK-2
(6-phosphofructo-2-kinase). The product of the action of PFK-2 (fructose-2,6-bisphosphate,
F2,6BP) is one of the most potent regulators of the rate of flux through
glycolysis and gluconeogenesis.

In liver the PKA-mediated phosphorylation of PFK-2 results in conversion of the
enzyme from a kinase that generates F2,6BP to a phosphatase that removes the
2-phosphate thus reducing the levels of the potent allosteric activator of the glycolytic
enzyme 6-phosphfructo-1-kinase, PFK-1 and the potent allosteric inhibitor
of the gluconeogenic enzyme fructose-1,6-bisphosphatase (F1,-6BPase).

It is important to note that like many enzymes, there are multiple isoforms of PFK-2
(at least 4) and neither the liver or the skeletal muscle isoforms contain the AMPK
phosphorylation sites found in the cardiac and inducible (iPFK2) isoforms of PFK-2.

Inducible PFK-2 is expressed in the monocyte/macrophage lineage in response to pro-
inflammatory stimuli. The ability to activate the kinase activity by phosphorylation of
PFK-2 in cardiac tissue and macrophages in response to ischemic conditions allows these
cells to continue to have a source of ATP via anaerobic glycolysis. This phenomenon is
recognized as the Pasteur effect: an increased rate of glycolysis in response to hypoxia.

Of pathological significance is the fact that the inducible form of PFK-2 is commonly
expressed in many tumor cells and this may allow AMPK to play an important role in
protecting tumor cells from hypoxic stress. Indeed, techniques for depleting AMPK in
tumor cells have shown that these cells become sensitized to nutritional stress upon loss
of AMPK activity.

Whereas, stress and exercise are powerful inducers of AMPK activity in skeletal muscle,
additional regulators of its activity have been identified.

Insulin-sensitizing drugs of the thiazolidinedione family (activators of PPAR-γ, see
below) as well as the hypoglycemia drug metformin exert a portion of their effects
through regulation of the activity of AMPK.

As indicated above, the activity of the AMPK activating kinase, LKB1, is critical for
regulating gluconeogenic flux and consequent glucose homeostasis. The action of
metformin in reducing blood glucose levels

  • requires the activity of LKB1 in the liver for this function.

Also, several adipokines (hormones secreted by adipocytes) either stimulate or inhibit
AMPK activation:

  1. leptin and adiponectin have been shown to stimulate AMPK activation, whereas,
  2. resistininhibits AMPK activation.

Cardiac effects exerted by activation of AMPK also include

AMPK-mediated phosphorylation of eNOS leads to increased activity and consequent
NO production and provides a link between metabolic stresses and cardiac function.

In platelets, insulin action leads to an increase in eNOS activity that is

  • due to its phosphorylation by AMPK.

Activation of NO production in platelets leads to

  • a decrease in thrombin-induced aggregation, thereby,
  • limiting the pro-coagulant effects of platelet activation.

The response of platelets to insulin function clearly indicates why disruption in insulin
action is a major contributing factor in the development of the metabolic syndrome

Activation of AMPK leads to a reduction in the level of SREBP

  • a transcription factor &regulator of the expression of numerous
    lipogenic enzymes

Another transcription factor reduced in response to AMPK activation is

  • hepatocyte nuclear factor 4α, HNF4α
    • a member of the steroid/thyroid hormone superfamily.
    • HNF4α is known to regulate the expression of several liver and
      pancreatic β-cell genes such as GLUT2, L-PK and preproinsulin.
  • Of clinical significance is that mutations in HNF4α are responsible for
    • maturity-onset diabetes of the young, MODY-1.

Recent evidence indicates that the gene for the carbohydrate-response-element-
binding protein (ChREBP) is a target for AMPK-mediated transcriptional regulation
in the liver. ChREBP is rapidly being recognized as a master regulator of lipid
metabolism in liver, in particular in response to glucose uptake.

The target of the thiazolidinedione (TZD) class of drugs used to treat type 2 diabetes is
the peroxisome proliferator-activated receptor γPPARγ which

  • itself may be a target for the action of AMPK.

The transcription co-activator, p300, is phosphorylated by AMPK

  • which inhibits interaction of p300 with not only PPARγ but also
  • the retinoic acid receptor, retinoid X receptor, and
  • thyroid hormone receptor.

PPARγ is primarily expressed in adipose tissue and thus it was difficult to reconcile how
a drug that was apparently acting only in adipose tissue could lead to improved insulin
sensitivity of other tissues. The answer to this question came when it was discovered that the TZDs stimulated the expression and release of the adipocyte hormone (adipokine),
adiponectin. Adiponectin stimulates glucose uptake and fatty acid oxidation in skeletal
muscle. In addition, adiponectin stimulates fatty acid oxidation in liver while inhibiting
expression of gluconeogenic enzymes in this tissue.

These responses to adiponectin are exerted via activation of AMPK. Another
transcription factor target of AMPK is the forkhead protein, FKHR (now referred to as
FoxO1). FoxO1 is involved in the activation of glucose-6-phosphatase expression and,
therefore, loss of FoxO1 activity in response to AMPK activation will lead to reduced
hepatic output of glucose.

This concludes a very complicated perspective that ties together the thyroid hormone
activity, the hypophysis, diabetes mellitus, and AMPK tegulation of metabolism in the
liver, skeletal muscle, adipose tissue, and heart.  I also note at this time that there
nongenetic points to be made here:

  1. The tissue specificity of isoenzymes
  2. The modulatory role of AMP:ATP ratio in phosphorylation/dephosphorylation
    effects on metabolism tied to AMPK
  3. The tie in of stress or ROS with fast reactions to protect harm to tissues
  4. The relationship of cytokine activation and release to the above metabolic events
  5. The relationship of effective and commonly used diabetes medications to AMPK
    mediated processes
  6. The preceding presentation is notable for the importance of proteomic and
    metabolomic invetigations in elucidation common chronic and nongenetic diseases

 

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