Protein turnover and growth in the whole body, liver and kidney of the rat from the foetus to senility.

Changes in the growth and protein turnover (measured in vivo) of the rat liver, kidney and whole body were studied between 16 days of life in utero and 105 weeks post partum. Tissue and whole-body growth were related to changes in both cellular hyperplasia (i.e. changes in DNA) and hypertrophy (protein/DNA values) and to the protein composition within the enlarging tissue mass. The suitability of using a single large dose of phenylalanine for measuring the rates of protein synthesis during both pre- and post-natal life was established. The declining growth rates in the whole animal and the two visceral tissues were then explained by developmental changes in the fractional rates of protein synthesis and breakdown, turnover rates being age-for-age higher in the liver than in the kidney, which in turn were higher than those measured in the whole animal. The declining fractional rates of synthesis in both tissues and the whole body with increasing age were related to changes in the tissues' ribosomal capacity and activity. The fall in the hepatic rate between 18 and 20 days of foetal life (from 134 to 98% per day) corresponded to a decrease in both the ribosomal capacity and the rate of synthesis per ribosome. No significant changes in any of these parameters were, however, found in the liver between weaning (3 weeks) and senility (105 weeks). In contrast, the fractional synthetic (and degradative) rates progressively declined in the kidney (from 95 to 24% per day) and whole body (from 70 to 11% per day) throughout both pre- and post-natal life, mainly as a consequence of a progressive decline in the ribosomal capacity, but with some fall in the ribosomal activity also during foetal life. The age-related contributions of these visceral tissues to the total amount of protein synthesized per day by the whole animal were determined. The renal contribution remained fairly constant at 1.6-2.9%, whereas the hepatic contribution declined from 56 to 11%, with increasing age. Approximate-steady-state conditions were reached at, and between, 44 and 105 weeks post partum, the half-life values of mixed whole-body, kidney and liver proteins being 6.4, 3.0 and 1.5 days, respectively, at 105 weeks.     

Selenium,zinc, and thyroid hormones in healthy subjects

Iodothyronine 5′ deiodinase, which is mainly responsible for peripheral T₃ production, has recently been demonstrated to be a selenium (Se)-containing enzyme. The structure of nuclear thyroid hormone receptors contains Zinc (Zn) ions, crucial for the functional properties of the protein. In the elderly, reduced peripheral conversion of T₄ to T₃ with a lower T₃/T₄ ratio and overt hypothyroidism are frequently observed. We measured serum Se and RBC GSH-Px (as indices of Se status), circulating and RBC Zinc (as indices of Zn status), thyroid hormones and TSH in 109 healthy euthyroid subjects (52 women, 57 men), carefully selected to avoid abnormally low thyroid hormone levels induced by acute or chronic diseases or calorie restriction. The subjects were subdivided into three age groups. To avoid under- or malnutrition conditions, dietary records were obtained for a sample of 24 subjects, randomly selected and representative of the whole population for age and sex. Low T₃/T₄ ratios and reduced Se and RBC GSH-Px activity were observed only in the older group. A highly significant linear correlation between the T₃/T₄ ratio and indices of Se status was observed in the older group of subjects (r=0.54;p<0.002, for Se;r=0.50;p<0.002, for RBC GSH-Px). Indices of Zn status did not correlate with thyroid hormones, but RBC Zn was decreased in older as compared with younger subjects. We concluded that reduced peripheral T₄ conversion is related to impaired Se status in the elderly.     

Effects of hypothyroidism on RNA synthesis in the adult rat brain

In this study we investigated the effects of hypothyroidism on adult brain RNA synthesis. Our data show that in the cerebral hemispheres of hypothyroid rats there is a decrease in microsomal RNA content and microsomal [³H]uridine incorporation. Sucrose gradient analysis revealed that these changes are mainly associated with free ribosomes and subunits and reflect changes in rRNA. The above changes are accompanied by a decrease in RNA polymerase I activity. All of the above mentioned changes returned to normal after thyroxine (T₄) treatment. In contrast to RNA polymerase I, RNA polymerase II activity was not affected. However, electrophoretic analysis of the in vitro poly(A)⁺RNA translation products revealed that hypothyroidism affects a few mRNAs. These results indicate that thyroid hormones have a role in adult brain tissue metabolism.     

Nongenomic signaling pathways triggered by thyroid hormones and their metabolite 3‐iodothyronamine on the cardiovascular system

Thyroid hormones play a wide range of important physiological activities in almost all organism. As changes in these hormones levels—observed in hypothyroidism and hyperthyroidism—promote serious derangements of the cardiovascular system, it is important to know their mechanisms of action. Although the classic genomic actions which are dependent on interaction with nuclear receptors to modulate cardiac myocytes genes expression, there is growing evidence about T₃ and T₄‐triggered nongenomic pathways, resulted from their binding to plasma membrane, cytoplasm, or mitocondrial receptors that leads to a rapidly regulation of cardiac functions. Interestingly both actions converge to amplify thyroid hormone effects on cardiovascular system. T₃ and T₄ nongenomic actions modify inotropic and chronotropic effects, cardiac action potential duration, cardiac growth, and myocyte shape by protein translation through protein kinases‐dependent signaling cascades, which include PKA, PKC, PI3K, and MAPK, and changes on ion channels and pumps activity. In respect to the decreased systemic vascular resistance seen in hyperthyroidism, T₃ appears to activate NOS or ATP‐sensitive K⁺ channels. In addition, a novel biologically active T₄‐derived metabolite has been described, 3‐iodothyronamine, T₁AM, which also acts through membrane receptors to mediate nongenomic cardiac effects. This metabolite influences the physiological manifestations of thyroid hormone actions by inducing opposite effects from those stimulated by T₃ and T₄, such as negative inotropic and chronotropic effects. Therefore, beyond genomic and nongenomic effects of thyroid hormones, it is crucial for there to be an equilibrium between T₃ or T₄ and T₁AM levels for maintaining cardiac homeostasis. J. Cell. Physiol. 226: 21–28, 2010. © 2010 Wiley‐Liss, Inc.     

Regulation of mitochondrial protein turnover by thyroid hormone(s)

1. The effect of thyroidectomy on turnover rates of liver, kidney and brain mitochondrial proteins was examined. 2. In the euthyroid state, liver and kidney mitochondria show a synchronous turnover with all protein components showing more or less identical half-lives compared with the whole mitochondria. The brain mitochondrial proteins show asynchronous turnover, the soluble proteins having shorter half-lives. 3. Mitochondrial DNA (m-DNA) of liver and kidney has half-lives comparable with that of whole mitochondria from these tissues. 4. Thyroidectomy results in increased half-lives of liver and kidney mitochondria, with no apparent change in the half-life of brain mitochondria. 5. A detailed investigation of the turnover rates of several protein components revealed a significant decrease in the turnover rates of mitochondrial insoluble proteins from the three tissues under study. 6. The turnover rates of m-DNA of liver and kidney show a parallel decrease. 7. Thus it is apparent that thyroid hormone(s) may have a regulatory role in maintaining the synchrony of turnover of liver and kidney mitochondria in the euthyroid state. Turnover of brain mitochondria may perhaps be regulated by some other factor(s) in addition to thyroid hormone(s). 8. It seems likely that during mitochondrial turnover m-DNA and insoluble proteins may constitute a major unit. 9. The mitochondrial protein contents of the three tissues are not affected by thyroidectomy. 10. No correlation was seen between the turnover rate of mitochondria and cathepsin activity in any of the tissues under study in normal or thyroidectomized animals. 11. On the other hand, mitochondrial proteinase activity shows good correlation with the turnover rates of mitochondria in normal animals, and a parallel decrease in activity comparable with the decreased rates of turnover is observed after thyroidectomy. 12. It is concluded that mitochondrial proteinase activity may play a significant role in their protein turnover.     

Replacement perfusion of cultured eucaryotic cells: A method for the accurate measurement of the rates of growth,protein synthesis,and protein turnover

The fractional rates of protein synthesis (k_s) and degradation (k_p) were studied in the myeloma cell line SP2/0-AG14 grown at different rates (k_g). Cells in spinner flask suspension cultures were maintained at constant cellular density for prolonged periods by replacement perfusion of labeling medium at a rate equivalent to the rate of growth. Total protein synthesis was calculated from the specific-radioactivity of labeled L-leucine in the precursor (medium) and cellular protein. Fractional synthesis rates determined by approach to equilibrium labeling were the same as those determined by equilibrium-pulse labeling kinetics and pulse-chase kinetics. The rate of protein degradation was determined from the established relationship k_g = k_s – k_p. Protein synthesis rates remained constant over a threefold range in the rate of cell growth. At relatively slow growth rates (k_g = 0.017/hr) turnover represented a major fraction of total synthesis (k_p = 0.032/hr = 0.65ks). At rapid growth rates (k_g = 0.058/hr) the value of k_p was less than 0.005/hr. No major difference was observed between the k_s determined for individual cellular proteins (separated by SDS-polyacrylamide (7.5%) gel electro-phoresis) from rapid- and slow-growing cultures. Thus, with an invariable k_s, any change in growth rate is due to an inverse change in the rate of turnover. Since turnover is the balance between synthesis and degradation and since synthesis is unchanging then changes in the growth rate of SP2/0-AG14 should be due to changes in the rate of protein degradation. Experiments were therefore performed to determine the origin of the degradative machinery, ie, cytosolic or lysosomal; autolysis of prelabeled cellular protein (in vitro) was observed only at acidic pH (4.2) and WUS totally inhibited by addition of lcupcptin (10 μM) and pepstatin (2 μM), the specific inhibitors of lysosomal cathepsins B (L) and D, respectively. Since growth rate appears to be regulated by the alterations in the rate of protein degradation and degradation (in vitro) in SP2/0-AG14 appearsto be lysosomal, then one should be able to alter the rate of cellular growth by interfering with rate of lysosomal proteolysis. Indeed, when the lysosomotropic amine NH ₄Cl (10 mM) is added to cells growing with a k_g of 0.018/hr ± 0.001 (k_s = 0.050/hr ± 0.002) the growth rate increased to 0.051/hr ± 0.002 without change in the rate of protein synthesis (k_s = 0.049/hr ± 0.003). It is suggested from our data that the cellular growth rate of SP2/0-AG14 is regulated by the lysosomal apparatus; whether this regulation is itself regulated by either a specific compartmentalization of the lysosomal proteinases and/or their substrates or by endogenous protease inhibitors, should prove to be an exciting area for future investigation.     

Thyroid hormones and neurotubule assembly in vitro during brain development

A new model has been used to evaluate the effects of thyroid hormones on brain development. This model is based on the assumption that the major effect of thyroid hormones is in regulating the rate of neurite growth of the rat brain at early stages of postnatal development. Microtubules were chosen as markers of neurite growth. We tested, therefore, whether the rate of microtubule assembly in vitro is under thyroid hormone control. The following results were obtained: The rate of tubulin assembly into microtubules in vitro seems to be thyroid hormone dependent: (a) in 15-day-old hypothyroid rats the rates of tubulin assembly in vitro are low, comparable to those levels found in normal rats on day 3; (b) normal rates of assembly in vitro are restored upon addition of very small amounts of microtubule fragments which act as nucleating centers in the process of microtubule formation; (c) addition of microtubule-associated proteins to a hypothyroid preparation restores maximal assembly rates; similar results were obtained on adding one of the microtubule-associated proteins (purified tau protein); (d) physiological amounts of thyroid hormones completely restore normal assembly rates provided that they are administered very early after birth; (e) the ability of tubulin to assemble maximally does not seem to be permanently impaired, since normal assembly rates are spontaneously restored when hypothyroidism is maintained until an adult stage; (f) normal microtubule assembly is observed when hypothyroidism is produced at an adult stage. The model which may be constructed from these results implies that thyroid hormones are required briefly after birth to accelerate the rate of microtubule assembly thus allowing intensive neurite growth during the critical period of brain development.     

Selenium and its relationship with selenoprotein P and glutathione peroxidase in children and adolescents with Hashimoto’s thyroiditis and hypothyroidism

The essential trace element selenium (Se) is required for thyroid hormone synthesis and metabolism. Selenoproteins contain selenocysteine and are responsible for biological functions of selenium. Glutathione peroxidase (GPx) is one of the major selenoproteins which protects the thyroid cells from oxidative damage. Selenoprotein P (SePP) is considered as the plasma selenium transporter to tissues. The aim of this study was to evaluate serum Se and SePP levels, and GPx activity in erythrocytes of children and adolescents with treated Hashimoto’s thyroiditis, hypothyroidism, and normal subjects.Blood samples were collected from 32 patients with Hashimoto’s thyroiditis, 20 with hypothyroidism, and 25 matched normal subjects. All the patients were under treatment with levothyroxine and at the time of analysis all of the thyroid function tests were normal. GPx enzyme activity was measured by spectrophotometry at 340 nm. Serum selenium levels were measured by high-resolution continuum source graphite furnace atomic absorption. SePP, TPOAb (anti-thyroid peroxidase antibody), and TgAb (anti-thyroglobulin antibody) were determined by ELISA kits. T₄, T₃, T₃ uptake and TSH were also measured.Neither GPx activity nor SePP levels were significantly different in patients with Hashimoto’s thyroiditis or hypothyroidism compared to normal subjects. Although GPx and SePP were both lower in patients with hypothyroidism compared to those with Hashimoto’s thyroiditis and normal subjects but the difference was not significant. Serum Se levels also did not differ significantly in patients and normal subjects. We did not find any correlation between GPx or SePP with TPOAb or TgAb but SePP was significantly correlated with Se.Results show that in patients with Hashimoto’s thyroiditis or hypothyroidism who have been under treatment with levothyroxine and have normal thyroid function tests, the GPx, SePP and Se levels are not significantly different.     

Hormonal regulation of ornithine aminotransferase biosynthesis in rat liver and kidney.

The relative rates of ornithine aminotransferase (OAT) synthesis in vivo were studied by pulse-labeling rats with [4,5-³H]leucine, isolating the mitochondrial enzyme protein by immunoprecipitation with a monospecific antibody, dissociating the immunoprecipitates on sodium dodecyl sulfate-acrylamide gels, and determining the radioactivity in OAT. After 4 days of treatment with triiodothyronine (T₃), both the enzyme activity level and the relative synthetic rate of OAT in rat kidney were elevated over twofold. The level of hepatic OAT activity was unaffected by this treatment. Thyroidectomy caused a 50% drop in the basal level of OAT activity and synthesis in kidney but not in liver. Although the basal levels of activity and synthesis of both renal and hepatic OAT were unaffected by adrenalectomy, the glucagon induction of the enzyme in liver was enhanced by about one-third and the T₃ induction in kidney was suppressed 50% by this operation. After 4 days of treatment with estrogen, both the enzyme activity level and the relative synthetic rate of OAT in male rat kidney were elevated nearly 10-fold. Hepatic OAT activity and synthesis were unaffected by this regimen. Thyroidectomy almost completely abolished the estrogen induction of OAT in kidney. OAT induction by estrogen could be restored by treating thyroidectomized rats with T₃. Simultaneous administration of T₃ plus estrogen to intact rats produced a multiple effect, resulting in a striking 20-fold induction of renal OAT. Although administration of either T₃ or estrogen causes an increase in the synthesis of immunoprecipitable OAT protein in rat kidney, each of these hormones may induce OAT by a different mechanism.     

Triiodothyronine regulated tubulin biosynthesis in oligodendrocytes during myelinogenesis

l-Triiodothyronine (T₃) is shown to stimulate the biosynthesis of tubulin in oligodendrocytes isolated from rat brains at different stages of myelinogenesis. The hormone sensitivity appears around day 11, reaches a maximum at day 15 and disappears by day 25 after birth. Dose response studies show that the optimal stimulation of tubulin in the oligodendrocytes from 15 day rat brain occurs with 0.045 nM T₃ in contrast to 4.5 nM T₃ that was previously shown to promote a similar age-dependent induction of tubulin in the astroglial cells from neonatal rat brain. Exposure of the oligodendrocytes to optimal dose of T₃ (0.045 nM) for 2 h elicits a marked and almost selective increase in the level of tubulin. Higher concentrations of T₃ induce additional proteins resulting in a loss of this sensitivity. Studies on the synthesis and turnover of ³⁵S-labeled tubulin show that the stimulation of tubulin by T₃ is primarily due to enhanced synthesis of the protein. Pulse chase experiments reveal that the half life of tubulin is about 5.5 h and that it remains unaffected by T₃. The crucial role of thyroid hormones and the possible function of tubulin in the two most critical phases of brain maturation viz. synaptogenesis and myelinogenesis is discussed.     

Blood Biochemistry,Thyroid Hormones,and Oxidant/Antioxidant Status of Guinea Pigs Challenged with Sodium Arsenite or Arsenic Trioxide

The present experiment aimed to compare the two most commonly used compounds of arsenic (sodium arsenite and arsenic trioxide) for their effect on blood metabolites, thyroid hormones, and oxidant/antioxidant status in guinea pigs. Twenty-one adult guinea pigs were randomly divided into three equal groups. Animals in group T₁ (control) were fed a basal diet, whereas 50 ppm arsenic was added in the basal diet either as sodium arsenite (T₂) or arsenic trioxide (T₃) and fed for 11 weeks. Serum aspartate aminotransferase and alanine aminotransferase activities were significantly increased along with a decrease in blood hemoglobin level in both the arsenic-administered groups. The level of erythrocytic antioxidants (catalase, superoxide dismutase, reduced glutathione, glutathione-S-transferase, and glutathione reductase) was decreased and lipid peroxidation was elevated upon arsenic exposure. Serum thyroid hormone levels were reduced and arsenic levels in tissues increased in both the arsenic-exposed groups, irrespective of the arsenic compound. Thus, sodium arsenite and arsenic trioxide exerted similar adverse effects on blood metabolic profile, antioxidant status, and thyroid hormones in guinea pigs.     

The effects of surgical stress and short-term fasting on protein synthesis in vivo in diverse tissues of the mature rat.

1. We measured fractional rates of protein synthesis, capacities for protein synthesis (i.e. RNA/protein ratio) and efficiencies of protein synthesis (i.e. protein-synthesis rate relative to RNA content) in fasted (24 or 48 h) or fasted/surgically stressed female adult rats. 2. Of the 15 tissues studied, fasting caused decreases in protein content in the liver, gastrointestinal tract, heart, spleen and tibia. There was no detectable decrease in the protein content of the skeletal muscles studied. 3. Fractional rates of synthesis were not uniformly decreased by fasting. Rates in striated muscles, uterus, liver, spleen and tibia were consistently decreased, but decreases in other tissues (lung, gastrointestinal tract, kidney or brain) were inconsistent or not detectable, suggesting that, in many tissues in the mature rat, protein synthesis was not especially sensitive to fasting. 4. In fasting, the decreases in fractional synthesis rate resulted from changes in efficiency (liver and tibia) or from changes in efficiency and capacity (heart, diaphragm, plantaris and gastrocnemius). In the soleus, the main change was a decrease in capacity. 5. Surgical stress increased fractional rates of protein synthesis in diaphragm (where there were increases in both efficiency and capacity) by about 50%, in liver by about 20%, in spleen by about 40%, and possibly also in the heart. In liver and spleen, capacities were increased. In other tissues (including the skeletal muscles), the fractional rates of protein synthesis were unaffected by surgical stress.     

Short-term effects of thyroid hormones during development: Focus on signal transduction

Extranuclear or nongenomic effects of thyroid hormones are mediated by receptors located at the plasma membrane or inside cells, and are independent of protein synthesis. Recently the αVβ3 integrin was identified as a cell membrane receptor for thyroid hormones, and a wide variety of nongenomic effects have now been shown to be induced through binding of thyroid hormones to this receptor. However, also other thyroid hormone receptors can produce nongenomic effects, including the cytoplasmic TRα and TRβ receptors and probably also a G protein-coupled membrane receptor, and increasing importance is now given to thyroid hormone metabolites like 3,5-diiodothyronine and reverse T₃ that can mimick some nongenomic effects of T₃ and T₄. Signal transduction from the αVβ3 integrin may proceed through at least three independent pathways (protein kinase C, Src or mitogen-activated kinases) but the details are still unknown. Thyroid hormones induce nongenomic effects on at least three important Na⁺-dependent transport systems, the Na⁺/K⁺-ATPase, the Na⁺/H⁺ exchanger, and amino acid transport System A, leading to a mitogenic response in embryo cells; but modulation of the same transport systems may have different roles in other cells and at different developmental stages. It seems that thyroid hormones in many cases can modulate nongenomically the same targets affected by the nuclear receptors through long-term mechanisms. Recent results on nongenomic effects confirm the old theory that the primary role of thyroid hormones is to keep the steady-state level of functioning of the cell, but more and more mechanisms are discovered by which this goal can be achieved.     

Effects of excess thyroid hormone on cell death,cell proliferation,and new neuron incorporation in the adult zebra finch telencephalon

Widespread telencephalic neuronal replacement occurs throughout life in birds. We explored the potential relationship between thyroxine (T₄) and cell turnover in the adult male zebra finch. We found that many cells in the zebra finch brain, including long‐projection neurons in the high vocal center (HVC), stained positively with an antibody to thyroid hormone receptors (TR). Labeling was generally weak in the ventricular zone (VZ) that gives rise to new neurons but some proliferative VZ cells and/or their progeny, identified by [³H]‐thymidine labeling, co‐labeled with anti‐TR antibody. Acute T₄ treatment dramatically increased the number of pyknotic and TUNEL‐positive cells in HVC and other telencephalic regions. In contrast, degenerating cells were never observed in the archistriatum or sub‐telencephalic regions, suggesting that excess T₄ augments cell death selectively in regions that show naturally occurring neuronal turnover. VZ mitotic activity was not altered shortly after acute T₄ treatment at a dosage that stimulated cell death, although [³H]‐labeling intensity per cell was slightly reduced. Moreover, the incorporation rates for neurons formed shortly before or after acute hormone treatment were no different from control values. Chronic T₄ treatment resulted in a reduction in the total number of HVC neurons. Thus, hyperthyroidism augmented neuronal death, which was not compensated for by neuronal replacement. Collectively, these results indicate that excess T₄ affects adult neuronal turnover in birds, and raises the possibility that thyroxine plays an important role in the postnatal development of the avian brain and vocal behavior. © 2002 Wiley Periodicals, Inc. J Neurobiol 51: 323–341, 2002     

Increased Oxidative Metabolism and Neurotransmitter Cycling in the Brain of Mice Lacking the Thyroid Hormone Transporter Slc16a2 (Mct8)

Mutations of the monocarboxylate transporter 8 (MCT8) cause a severe X-linked intellectual deficit and neurological impairment. MCT8 is a specific thyroid hormone (T₄ and T₃) transporter and the patients also present unusual abnormalities in the serum profile of thyroid hormone concentrations due to altered secretion and metabolism of T₄ and T₃. Given the role of thyroid hormones in brain development, it is thought that the neurological impairment is due to restricted transport of thyroid hormones to the target neurons. In this work we have investigated cerebral metabolism in mice with Mct8 deficiency. Adult male mice were infused for 30 minutes with (1-¹³C) glucose and brain extracts prepared and analyzed by ¹³C nuclear magnetic resonance spectroscopy. Genetic inactivation of Mct8 resulted in increased oxidative metabolism as reflected by increased glutamate C4 enrichment, and of glutamatergic and GABAergic neurotransmissions as observed by the increases in glutamine C4 and GABA C2 enrichments, respectively. These changes were distinct to those produced by hypothyroidism or hyperthyroidism. Similar increments in glutamate C4 enrichment and GABAergic neurotransmission were observed in the combined inactivation of Mct8 and D2, indicating that the increased neurotransmission and metabolic activity were not due to increased production of cerebral T₃ by the D2-encoded type 2 deiodinase. In conclusion, Mct8 deficiency has important metabolic consequences in the brain that could not be correlated with deficiency or excess of thyroid hormone supply to the brain during adulthood.     

Selenoenzyme activities in selenium- and iodine-deficient sheep

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

Urinary iodine and thyroid function in a population of healthy pregnant women in the North of Spain

BackgroundIodine is an essential trace element for the synthesis of thyroid hormones, which are keys in maternal metabolism during pregnancy as well as in neurological development during fetal and postnatal life. This was a prospective study on iodine status and thyroid function in women during pregnancy in the Basque country to assess whether there was any relationship among maternal urinary iodine, maternal thyroid function and thyrotropin (TSH) in newborns, and to explore any difference in women experiencing miscarriages.MethodsWe analyzed TSH, free T₄ (FT₄), free T₃ (FT₃), thyroid peroxidase antibody (TPO-Ab) titers in serum and urinary iodine concentrations (UIC) in 2104 women in the first trimester of pregnancy and in 1322 of them in their second trimester. We obtained neonatal TSH levels in 1868 cases.ResultsIn the first (T1) and second trimesters (T2), the median UICs were 88.5 μg/L and 140 μg/L, respectively. No relationship was found between UIC and FT₄, or maternal and neonatal TSH. In T1 and T2, 9.7% and 7.5% of women were TPO-Ab positive, respectively. The total miscarriage rate was 10%. The percentage of miscarriages in healthy women was 8.9%, lower than in women with overt hypothyroidism (21.2%; p < 0.001) and than in women with subclinical hypothyroidism (15.6%; p < 0.025). The miscarriage rate was not higher in TPO-Ab-positive women.ConclusionsIn this study most women had iodine deficiency during pregnancy. Neonatal TSH is not correlated with maternal UIC during pregnancy. Pregnant women with hypothyroidism have a higher rate of miscarriages.     

Tri-iodothyronine effects on Sertoli cell protein turnover in the prepubertal pig

The direct effect of Tri-iodothyronine (T₃: 0.1–100 nM) on protein turnover was studied using primary cultures of Sertoli cells isolated from immature piglet testis. The results demonstrate that T₃ significantly increases protein synthesis without altering the protein degradation rate. These data and previous ones, showing the presence of specific T₃ receptors in Sertoli cell nuclei, indicate that T₃ plays a fundamental role in the early regulation of porcine Sertoli cell growth and maturation.     

Dynamics of Thyroid Hormones at Early Stages of Development of the Sturgeon Acipenser güldenstadti

Using radioimmunological method, the level and dynamics of thyroid hormones, thyroxine (T₄) and triiodothyronine (T₃) were studied in eggs, embryos, and pre-larvae of the Russian sturgeon Acipenser güldenstadti L. The level of hormones in eggs was higher than in the individuals at the stage of hatching. In embryogenesis the content of T₄ and T₃ hormones changed simultaneously, while in pre-larvae, synchronization was absent. The maximal T₄ values in sturgeon pre-larvae were recorded not long before transition to active nutrition. The T₄ level was statistically significantly higher in eggs and larvae developed from the eggs with a high degree of fertility. The problem of participation of thyroid hormones in processes of development and formation of adaptive mechanisms in early ontogenesis of sturgeons is discussed.