NEW INSIGHTS INTO THE HYPOTHALAMIC-PITUITARY-THYROID AXIS.

The discovery of thyrotropin releasing hormone (TRH) in 1969 was the definitive step in decoding the hypothalamic-pituitary thyroid (HPT) axis, thereby opening up the era of neuroendocrinology, while it also revolutionized the diagnostic and therapeutic approach to patients with thyroid diseases. TRH, produced in the hypothalamus, is the central regulator of the HPT. It functions via neurons originating in the paraventricular nucleus (PVN), which integrates multiple neuronal and humoral signals and resets the HPT axis according to variations of external and internal environmental conditions. The TRH activates TSH in the pituitary that stimulates the secretion of thyroxine from thyroid which, in turn, exerts a negative feedback on TSH and TRH secretion. However, various factors are involved in the regulation of the HPT axis. Leptin has both indirect and direct effects on TRH regulation, the former by regulating agouti-related peptide (AGRP) in the arcuate nucleus (ARN) that antagonizes the α-MSH stimulatory activity on pro-TRH gene expression in the PVN, and the latter by stimulating hypothalamic TRH expression, TRH transcription via stimulation of pro-convertase 1 and 2 expression, which lead to enhanced processing of pro-TRH into TRH. The interplay of TRH with leptin and the recently reported influence of ghrelin on the HPT axis can alter the setpoint of the axis. The polyphenol resveratrol, as recently observed, exerts an anxiolytic and antidepressant activity in subclinical hypothyroid (SCH) rats. Resveratrol, by decreasing both TSH and TRH mRNA expression, regulates the HPT axis, while in parallel it regulates the Wnt/ß-catenin pathway in the hippocampus. These findings open up possibilities for the therapeutic use of resveratrol as coadjuvant, especially in overt and SCH states marked by anxiety and depression. The clinician should be aware of clinical changes that can invalidate the normal regulation of the HPT axis, the most commonly observed being medications and comorbidities.

The Role of Iodine and Selenium in Autoimmune Thyroiditis.

Iodine and selenium (Se) are both essential elements to thyroid hormone economy, while they represent key players in the development of autoimmune thyroiditis.Chronic high iodine intake has been associated in various studies with increased frequency of autoimmune thyroiditis. In susceptible individuals, iodine excess increases intra-thyroid infiltrating Th17 cells and inhibits T regulatory (TREG) cells development, while it triggers an abnormal expression of tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) in thyrocytes, thus inducing apoptosis and parenchymal destruction. As was shown in a mouse model, high iodine supply leads to changes in the immunogenicity of the thyroglobulin molecule, upregulation of vascular intercellular adhesion molecule-1 (ICAM-1), and reactive oxygen species (ROS) generation in the thyrocytes. Serum Se levels were found decreased in Hashimoto thyroiditis and especially in Graves' disease as well as in thyroid-associated ophthalmopathy patients, the levels being related to the pathogenesis and outcome. Selenium is strongly involved, via the variable selenoproteins, in antioxidant, redox, and anti-inflammatory processes. Selenium enhances CD4+/CD25 FOXP3 and T regulatory cells activity while suppressing cytokine secretion, thus preventing apoptosis of the follicular cells and providing protection from thyroiditis. Selenium supplementation may be useful in autoimmune thyroid diseases, though, while usually well-tolerated, it should not be universally recommended, and it is also likely to be helpful for those with low Se status and autoimmunity. Broadly speaking, the achievement and maintenance of "selenostasis" as well as adequate urinary iodine excretion are mandatory to control disease, while, putatively, they may additionally be critical to preventing disease.

Hypothyroidism and depression: salient aspects of pathogenesis and management.

Hypothyroidism has been linked to depression as there is irrefutable evidence that it triggers affective disease and psychic disorders. Depressive patients have a higher frequency of hypothyroidism and patients with hypothyroidism have a higher occurrence of depressive syndrome. Hypothyroidism exhibits considerable alterations in blood flow and glucose metabolism in the brain. Furthermore, patients with major depression may have structural abnormalities of the hippocampus that can affect memory performance. Thyroid peroxidase antibodies have, moreover, been positively associated with trait markers of depression. Depressive symptomatology is variable and is influenced by susceptibility and the degree, though not always, of thyroid failure. In addition, glucose homeostasis and rapid weight loss have been associated to thyroid hormones and increased depressive symptoms. Thyroxine treatment in patients older than 65 years does not improve cognition. In contrast, T3 administration is the therapy of choice in patients with resistance to antidepressive drugs, and especially to SSIR. Genetic variants of thyroid hormone transporters or of deiodinases I and II may predispose to depression and, therefore, a personalized approach should be implemented.

Resveratrol and its impact on aging and thyroid function.

Resveratrol, the naturally occurring polyphenolic compound characterized by anti-oxidative, anti-inflammatory and apoptotic properties, appears to contribute substantially to cardioprotection and cancer-prevention. In addition, resveratrol is believed to regulate several biological processes, mainly metabolism and aging, by modulating the mammalian silent information regulator 1 (SIRT1) of the sirtuin family. Resveratrol may arrest, among various tumors, cell growth in both papillary and follicular thyroid cancer by activation of the mitogen-activated protein kinase (MAPK) signal transduction pathway as well as increase of p53 and its phosphorylation. Finally, resveratrol also influences thyroid function by enhancing iodide trapping and, by increasing TSH secretion via activation of sirtuins and the phosphatidylinositol- 4-phosphate 5 kinase γ (PIP5Kγ) pathway, positively affects metabolism.

Gender, age, puberty, and BMI related changes of TSH and thyroid hormones in schoolchildren living in a long-standing iodine replete area.

The aim of the work was to assess thyroid function in children and adolescents in an iodine replete area and to explore possible effects of age, gender, puberty, and adiposity. Thyrotropin (TSH), total triiodothyronine (T (3)), total thyroxine (T (4)), free thyroxine (FT (4)), and the T (4)/T (3) ratio were determined for 440 schoolchildren (200 boys and 240 girls), aged 5-18 years, living in an iodine replete region. Body Mass Index (BMI), BMI standard deviation score (BMI-SDS), and Body Surface Area (BSA) were calculated. In girls there was a negative correlation of TSH, T (3), and FT (4) values with age. In boys there was a negative correlation only of T (3) values with age. Girls had lower TSH, T (4), and T (3) values, whereas boys had only lower T (3) values at puberty compared to the prepubertal stage. Girls had lower TSH values than boys (p<0.03) only at puberty. BMI-SDS in boys and girls were 0.21 and 0.03, respectively. BMI-SDS was not related to TSH, T (4), or T (3) in either gender, whereas it was negatively related to T (4)/T (3) ratio in boys and to FT (4) in girls. We conclude that estrogens may exert a suppressive effect on the pituitary-thyroid axis after puberty. TSH values are not correlated with BMI-SDS, whereas T (4)/T (3) ratio in boys and FT (4) in girls are negatively correlated with BMI-SDS.

Selenium and inflammation: underlying anti-inflammatory mechanisms.

The essential trace element selenium (Se), in the form of selenoproteins, plays a pivotal role in the antioxidant defense system of the cell. There is evidence that Se may confer benefits in patients with inflammatory disease and even infectious diseases like HIV. Furthermore, in patients with severe sepsis, characterized by an increase in reactive oxygen species and low endogenous anti-oxidative capacity, as well as in patients with systemic inflammatory response syndrome, Se supplementation may reduce mortality and improve the clinical outcome, respectively. The nuclear factor kappa-B (NF-kappaB) signaling pathway has been associated with enhanced inflammatory response and its activation has been significantly correlated with interleukin-6 and TNF-alpha production. Selenium may inhibit the activation of NF-kappaB by modulating selenoprotein genes expression. Moreover, Se supplementation in chronic inflammation restores the depleted hepatic and serum Se levels by increasing selenoprotein biosynthesis leading to suppressed CRP production thereby attenuating the inflammatory process. Se increases shedding of L-selectin from monocytes while decreasing soluble L-selectin, which has been reported to be associated with high mortality in patients with sepsis. These mechanisms are likely to contribute to the modulatory effects of an increased Se status on the inflammatory response. This review evaluates some apparently key mechanisms of the anti-inflammatory action of selenium and advocates Se supplementation as a modulator of inflammatory response in infectious and autoimmune disease. Prospective, randomized, controlled studies must be performed to provide a greater degree of certainty.

Changes in metabolism of TRH in euthyroid sick syndrome.

OBJECTIVE: The aim of this study was to examine the metabolism of a simple dose, intravenously administered TRH bolus of 200 microg, in patients with euthyroid sick syndrome (ESS). PATIENTS AND METHODS: A TRH test was performed on ten ESS patients and ten controls upon admission (d1) and after recovery (d2). Blood samples were collected at 0, 10, 20 and 30min after TRH injection. We analyzed the volume of distribution (V(d)), the plasma clearance rate (PCR), the fractional clearance rate (FCR), the half-life (t(1/2)) and the TSH response to the injection of TRH. RESULTS: All patients had lower tri-iodothyronine (T(3)) levels compared with controls (0.9 +/- 0. 1nmol/l vs 1.9 +/- 0.1 nmol/l; P < 0.0001; mean +/- S.D.; paired t-test). In addition, the V(d) (16.7 +/- 5.9/l vs 30.6 +/- 0.6/l; P < 0.0005) and PCR (2.0 +/- 0.80 l/min vs 3.3 +/- 0.25 l/min; P <0. 0005) were found statistically lowered in patients than in controls, whereas FCR (0.119 +/- 0.01 permin vs 0.110 +/- 0.01 per min; P < 0. 025) was found increased in patients as opposed to controls. The t(1/2) of exogenously administered TRH was increased in ESS compared with controls (7.2 +/- 0.7 min vs 6.3 +/- 0.6 min; P <0.005). TSH response to TRH was found significantly repressed at 10, 20 and 30 min after TRH injection. On d2, these findings had reverted to normal and no changes regarding the kinetics of TRH and the response of TSH could be detected between patients and controls. CONCLUSIONS: The results demonstrate an impairment of TRH metabolism in ESS. The findings may suggest altered enzymatic activity, responsible for TRH degradation in states of acute ESS. These changes might be involved in the pathogenesis of ESS and represent part of an adaptive mechanism to this syndrome.

Lack of substantial effects of raloxifene on thyroxine-binding globulin in postmenopausal women: dependency on thyroid status.

Long-term estrogen therapy can modify thyroid hormone kinetics by increasing serum concentration of thyroxine-binding globulin (TBG). Raloxifene is a recently developed selective estrogen receptor modulator (SERM) for the treatment of osteoporosis, which possesses estrogenic and antiestrogenic properties. In a prospective and randomized study, we investigated the effects of raloxifene on TBG levels and on the serum concentrations of free thyroxine (FT4), thyroxine (T4), triiodothyronine (T3), and thyrotropin (TSH) in controls and in patients receiving TSH-suppressive doses of levothyroxine (LT4). Twenty-nine postmenopausal osteopenic (n = 14) and osteoporotic (n = 15) women were investigated over a period of 6 months. Group 1 (n = 15) included control patients and group 2 (n = 14) patients receiving TSH-suppressive dose of LT4. All patients were treated with raloxifene hydrochloride, 60 mg/d, for a period of 6 months. Serum basal TBG values were found higher in Group 1 compared to Group 2 (26.2 2 microg/mL vs. 21.4 2.1 microg/ml; p < 0.01). The TBG levels raised slightly in group 1 from 26.2 2 microg/mL to 28.6 3.1 microg/mL; p < 0.05 (in group 2 from 21.4 2.1 microg/mL to 22.2 2.3 microg/mL, not significant) after 3 months of treatment and failed to show any further significant change until the end of the study. Serum concentrations of T4, FT4, T3, and TSH levels changed insignificantly in both groups up to the completion of the study. Moreover, patients remained clinically euthyroid. Our findings may provide evidence that TBG levels, and consequently, thyroid function are not substantially affected by treatment with raloxifene. Additionally, TBG levels may also be influenced by small variations of thyroid function as subclinical hyperthyroidism.

Inhibitory action of oral thyrotropin-releasing hormone on the glucoregulatory response of the oral glucose tolerance test.

Thyrotropin-releasing hormone (TRH) has been found in the gastrointestinal tract, where it mainly exerts an inhibitory action. We used oral TRH, a stable and powerful formulation, to explore the glucoregulatory response of oral glucose tolerance test (OGTT) on obese patients with impaired glucose tolerance (IGT). Seven obese patients with IGT and eight controls were investigated. Three tests were performed on three separate days. On day 1, An oral TRH test: a 40 mg TRH tablet, was given. Blood samples for blood glucose (BG), proinsulin (PI), insulin (INS), C-peptide (CP), thyroxine (T4), triiodothyronine (T3), and thyrotropin (TSH) were collected every 30 minutes for 3 hours. On day 2, an OGTT with 75 g glucose was performed. On day 3, an oral TRH test was administered 30 minutes before the OGTT, and blood was collected every 30 minutes for 3 hours. Oral-TRH had no effect on basal BG and on pancreatic hormone secretion. Oral TRH, coupled with OGTT in both controls and obese patients, led to a significant inhibition of BG (p < 0.01), of CP (p < 0.001), and of INS (p < 0.001) during the first hour of administration, and afterward, there was only a very slight increase, compared with levels after only OGTT treatment. After OGTT, PI peaked at 90 minutes (9.4+/-3 ng/mL) in controls and at 60 minutes (12.7+/-2.5 ng/mL) in obese patients. TRH application prior to OGTT inhibited PI secretion for 90 minutes in controls, whereas in obese patients PI levels were decreased, not inhibited, during the OGTT. The mechanism of the inhibitory TRH action on OGTT-induced increase of BG and pancreatic hormone secretion is not clear. It could be due to inhibition of gastric motility, and on a paracrine effect that enhances secretion of somatostatin that then suppresses INS, CP, and possibly PI levels. The partial escape of PI from the TRH blockade in obese patients with IGT might indicate a diminished functioning capability of beta-cells and that TRH cannot affect the INS processing within the beta-cells in these patients.

Incidence of sideropenia and effects of iron repletion treatment in women with subclinical hypothyroidism.

Sideropenia affects ca. 20% of the world population, and iron dependent anemia is the most frequent type of anemia worldwide. The aim of the study was to investigate the incidence of sideropenia and dependent anemia in patients with subtle changes of the thyroid function, such as subclinical hypothyroidism (SH). 57 women with SH and 61 euthyroid controls (CG) were studied. Serum concentrations of T4, T3, TSH, anti-TPO, anti-Tg, ferrum (Fe), ferritin (Frt) total iron binding capacity (TIBC) and blood count were determined. In SH 17 patients (29.8%) presented low Fe levels (<50 microg/dl). 9 (15.7%) also had decreased Frt, confirming iron deficiency, whereas 8 patients presented additionally diminished hematocrit and hemoglobin levels, suggesting manifested sideropenic anemia. In CG, 10 persons (16%) had sideropenia, 6 (9.8%) had low Fe and Frt and only 3 (4.9%) had blood count alterations suggesting manifested sideropenic anemia. In SH, anti-TPO were positive in 39 patients (68%), whereas, in CG only 2 (3.2%) were positive. 8 patients with SH and manifested sideropenic anemia were treated with ironproteinsuccinylate (I-PSL), (80 mg Fe /day, for three months), a new iron compound. The repletion treatment safely led to the clinical and laboratory correction of sideropenia and showed a good tolerability. Furthermore, iron treatment provoked a minor increase of T4 and a mild decline of TSH, but the levels were not significant. These results suggest that sideropenia is a common finding in patients with slightly decreased thyroid activity, and that determination of Frt should be routinely advised. Finally, in the assessment of sideropenia and dependent anemia, evaluation of the thyroid function must be taken into account.

Prolactinomas in children and adolescents--consequences in adult life.

Prolactinomas in children and adolescents are rare. However, they represent, together with corticotropinomas, the most frequent types of pituitary tumors in adolescence. Most prolactin-secreting pituitary tumors are microprolactinomas but many, and particularly those in men, are macroadenomas. The clinical findings that would usually project into the adult life of patients, in other words the issue of transitory endocrinology from childhood to adulthood, are menstrual irregularities, infertility, short stature, osteopenia and/or osteoporosis, and sometimes psychometric abnormalities. The therapy of choice for both macro- and microprolactinomas is one of the new dopamine agonists, such as quinagolide or cabergoline. Recent evidence-based data have clearly promoted cabergoline as the first-line treatment. Cabergoline may normalize prolactin secretion, restore fertility in women and men. and induce tumor shrinkage. Today, transsphenoidal surgery should be considered only in patients with a large extrasellar extension.

Cardiovascular Risk in Patients with Subclinical Hypothyroidism.

Subclinical hypothyroidism (SCH) has been associated with increased cardiovascular mortality due to adverse effects mainly on lipids and blood pressure (BP). There is evidence that SCH, especially in patients with thyroid-stimulating hormone (TSH) >10mU/l, may increase cardiovascular risk. Some uncertainty exists regarding the association of SCH with BP; however, that the coexistence of SCH with BP and hypercholesterolaemia has a negative cardiovascular impact is beyond doubt. Insulin resistance, by modulating various risk factors including coagulation, may potentially increase cardiovascular risk. Periodic health examinations including screening has been advised in patients >35 years of age, while treatment with thyroxine should be tailored to each patient.

Environmental factors and thyroid autoimmunity.

Thyroid autoimmune disease, a multifactorial organ-specific autoimmune disorder, is marking a constant increase worldwide. It is thought to be caused by multiple environmental factors triggering autoimmune response in genetically susceptible individuals, though the exact mechanisms linking environmental factors to thyroid autoimmunity are not as yet well understood. Nevertheless, there is increasing evidence that mainly nutritive factors and environmental pollution by metals and chemicals (e.g. organochlorines, pesticides) are the main factors in the present-day spread of this disease. This review presents an overview of the current knowledge regarding environmental factors, their association with genetics and their impact on the immune system.

Oxidants, antioxidants in physical exercise and relation to thyroid function.

Intensive muscular exercise promotes the production of reactive oxygen species (ROS) in the working muscles and can impair athletic performance, particularly in conjunction with inadequate recovery. Mammals are protected against oxygen toxicity by a system of ROS scavengers composed of enzymatic and non-enzymatic components. Although antioxidant supplementation has recently been considered as a means to diminish or prevent damage from ROS, the specific antioxidant requirements of athletes are not known. Since thyroid function is essential for athletic performance, thyroid control should be undertaken in cases where there is any sign of thyroid dysfunction "of unknown etiology". Hyperthyroidism and hypothyroidism have been associated with increased production of ROS as well as related inflammatory response and myopathy. There is evidence that antioxidant supplementation combined with antithyroid treatment with methimazole could be useful in decreasing the oxidative stress.

Leptin TRH and ghrelin: influence on energy homeostasis at rest and during exercise.

The hypothalamus has long been recognized as a major site in the central nervous system (CNS) where a spectrum of internal and external environmental information is integrated for energy homeostasis. The isolation and sequencing of leptin in the mid 90 s, together with the demonstration of leptin administration's ability to correct the obesity syndrome in leptin-deficient ob/ob mice and humans by suppressing food intake and weight gain in laboratory rodents, confirmed the hypothesized existence of a direct humoral signal from adipose tissue to the hypothalamus, thus integrating the energy-related signals. In the 80 s, neuropeptide Y (NPY) was identified as a potent appetite-stimulating neuropeptide produced, released and acting locally within the hypothalamus. This is recognized as a major physiological appetite transducer and central neurochemical substrate receiving, interpreting and processing incoming information on energy status. More recently, ghrelin, produced in the stomach and released into the general circulation, has drawn attention as the other limb of the feedback circuit that stimulates appetite at NPY network level. Prolonged fasting suppresses serum leptin, while suppressing TSH secretion. Intervention with leptin replacement can prevent fasting-induced changes in TSH, suggesting that leptin regulates TSH. Low leptin levels in sportsmen and sportswomen as well as in recreational runners are consistent with reduction in body fat, but are also influenced by the presence of low insulin, hypothyroxemia, and elevated cortisol levels. These metabolic adaptations to chronic energy deficits indicate a role in leptin regulation. A study within the general population found that activity levels and leptin were significantly negatively associated in both sexes. Circulating ghrelin levels, however, do not change during energy expenditure.

Iodine uptake and loss-can frequent strenuous exercise induce iodine deficiency?

Most of the daily dietary iodine intake (approximately 90 %) will be excreted in the urine; measurement of urinary iodine excretion is thus routinely used as an index of dietary iodine intake. However, urinary excretion is not the only means of iodine loss. Subjects such as athletes or those participating in vigorous exercise can lose a considerable amount of iodine in sweat, depending on environmental factors such as temperature and humidity. In areas of lower to moderate dietary iodine intake, loss in sweat can equal that in urine. Although electrolyte loss in sweat is well-recognized and replacement strategies are adopted, there is less recognition of potential iodine loss. Crude calculations reveal that if sweat iodide losses are not replaced, dietary stores could be depleted in an athlete undergoing a regular training regime. The significance of these losses could be increased in areas where dietary iodine intake is lower in the summer months. Although there is little doubt that excessive sweating can induce a relative iodine deficiency state, there is no case as yet for iodine supplementation in those that take vigorous exercise. However, sustained iodine loss may have implications for thyroid status and possibly consequences for athletic performance.