Preparation of lipid-free tissue extracts for chromatographic determination of thyroid hormones and metabolites

Thyroid Hormone Metabolites Quantified in Pup and Adult Rat Cerebellum, Cortex and Whole-Brain Samples Using an Automated Online SPE-LC-MS/MS Method

Changes in thyroid hormone (TH) levels in rat brain at early developmental stages are correlated with adverse effects on offspring development. To characterize the ability of substances to interfere with the TH concentrations in, e.g., rat brain, it is essential to know the mean TH concentrations in this tissue under control conditions. In this publication, an online solid-phase extraction (SPE) liquid chromatography (LC) tandem mass spectrometry (MS/MS) method was validated and used to measure TH metabolites (T4, T3, rT3, T2 and T1) in the brains of untreated rats. Data on TH concentrations in the whole brain and separate data from the cerebellum and the cortex are shown. The corresponding samples were gathered from young rats at postnatal days (PND) 4 and 21/22 and from adult rats. The results show inter alia the high accuracy and precision of the method, and LOQs of 0.02 ng/mL were determined for T1, T2 and rT3 and of 0.15 ng/mL for T3 and T4. Technical variability is low, as shown by the relative standard deviations of 7.5-20%. For our rat model, we found that T4, T3 and T2 concentrations rise from PND4 to PND21, whereas the rT3 concentration decreases; as well as there is no statistical difference between TH concentrations in the male and female rat brain. This method is suitable to analyze TH metabolites in the brain and build up a database of historical TH concentrations in control rats. Together, this yields a robust diagnostic tool to detect potentially adverse disturbances of TH homeostasis in the most vulnerable anatomic structure.

Unveiling the nongenomic actions of thyroid hormones in adult mammalian brain: The legacy of Mary B. Dratman

A comprehensive review was conducted to compile the contributions of Mary B. Dratman and studies by other researchers in the field of nongenomic actions of thyroid hormones in adult mammalian brain. Dratman and her collaborators authored roughly half of the papers in this area. It has been almost fifty years since Dratman introduced the novel concept of thyroid hormones as neurotransmitters for the first time. The characterization of unique brain-region specific accumulation of thyroid hormones within the nerve terminals in adult mammals was a remarkable contribution by Dratman. It suggested a neurotransmitter- or neuromodulator-like role of thyroid hormone and/or its derivative, 3-iodothyronamine within adrenergic systems in adult mammalian brain. Several studies by other researchers using synaptosomes as a model system, have contributed to the concept of direct nongenomic actions of thyroid hormones at synaptic regions by establishing that thyroid hormones or their derivatives can bind to synaptosomal membranes, alter membrane functions including enzymatic activities and ion transport, elicit Ca2+/NO-dependent signaling pathways and induce substrate-protein phosphorylation. Such findings can help to explain the physiological and pathophysiological roles of thyroid hormone in psychobehavioral control in adult mammalian brain. However, the exact mode of nongenomic actions of thyroid hormones at nerve terminals in adult mammalian brain awaits further study.

Prenatal exposure to brain-specific anion transporter-1-specific monoclonal antibodies impairs cognitive function in post-natal life

Subclinical hypothyroidism is caused by thyroid hormone deficit and can lead to impairments in mood and cognition. In brain, supply with thyroxine (T4) is mediated by thyroid hormone transporters including the brain-specific anion transporter-1 (BSAT-1). In humans and rodents, BSAT-1 is expressed in brain microvessels and astrocytes. In this study, we tested whether exposure in utero with BSAT-1-specific monoclonal antibodies (MabBSAT) will affect the cognitive function of the progeny. On gestation day 16th, females were intravenously treated with MabBSAT, non-specific antibodies (control 1), and saline (control 2). 72h after injection, MabBSAT were still detectable in the rat brain while non-specific antibodies were found. Immunocytochemistry showed that MabBSAT can bind to cultured primary cerebrovascular rat cells. At the age of 1month, the progeny was subjected to the Y-maze test, novel object recognition test, passive avoidance test, and Morris water maze, which revealed significant impairments in the cognitive function in the MabBSAT-exposed progeny compared to both control progeny groups. Therefore, prenatal exposure to MabBSAT blocks brain BSAT-1 and limits T4 influx to the brain. This impairs the cognitive function in exposed progeny in the post-natal life.

Imaging triiodothyronine binding kinetics in rat brain: a model for studies in human subjects

Many lines of evidence indicate a role for thyroid hormones in the expression of cognitive and affective disorders. These conditions constitute a large proportion of the illness burden in the general population. Unfortunately, presently available diagnostic procedures cannot adequately identify these problems. To determine whether imaging studies of thyroid hormone kinetics in brain might be feasible in patients with these disorders, an autoradiographic method for measuring thyroid hormone kinetics was developed. Twenty-five awake adult rats received high specific activity [(125)I]-triiodothyronine (T(3)*). Brains were obtained at intervals from 5 through 300 min after i.v. hormone administration. Every 5th frozen section was thaw mounted and exposed to film. To determine whether T(3) was responsible for the autoradiographic images, the intervening sections were assembled while frozen in regional tissue pools and were extracted and then analyzed by high-performance liquid chromatography. The results demonstrated that radioactivity was almost entirely due to T(3)*( approximately 90%) while small amounts of hormone metabolites, including [(125)I]iodine accounted for the remainder. Regional concentrations of label in autoradiograms were measured by densitometry in hippocampus (CA1, CA2, CA3, and dentate gyrus), cerebellum (molecular and granular cell layers), caudate nucleus, and amygdala. Unexpectedly and interestingly, the results demonstrated that binding through 5 h was mainly irreversible. Regional values of the net uptake rate constant of T(3)* or influx constant, K(i), were determined from the time course of the T(3)* data, showing significant differences among regions. These results suggest that imaging of labeled thyroid hormone ligands by positron emission tomography or single photon emission computed tomography may be feasible and would potentially provide useful information relevant to T(3) processing in the brain during a variety of drug and disease-induced conditions.

Dynamic nongenomic actions of thyroid hormone in the developing rat brain

Two well-characterized nongenomic actions of thyroid hormone in cultured brain tissues are: 1) regulation of type 2 iodothyronine 5'deiodinase (D2) activity and 2) regulation of actin polymerization. In particular, the latter is likely to have profound effects on neuronal migration in the developing brain. In this study, we determined whether these nongenomic actions also occurred in vivo during brain development. Neonatal hypothyroidism was induced by propylthiouracil given to pregnant dams beginning on d17 of gestation and continued throughout the neonatal period. On postnatal d 14, rats were injected with either cold or [(125)I]-labeled iodothyronines and killed sequentially after injection. In contrast to reports in the adult rat, all three iodothyronines readily and equally entered developing brain tissues. As expected, cerebrocortical D2 activity was markedly elevated in the hypothyroid brain and both reverse T(3) (rT(3)) and T(4) rapidly decreased D2 to euthyroid levels within 3 h. Furthermore, cerebellar G-actin content in the hypothyroid rat was approximately 5-fold higher than in the euthyroid rat. Again, both rT(3) and T(4) rapidly decreased the G-actin content by approximately 50%, with a reciprocal increase in F-actin content to euthyroid levels without altering total actin. Neither T(3) nor vehicle had any effect on D2 activity in the cortex or G- or F-actin content in the cerebellum. The thyroid hormone-dependent regulation of actin polymerization in the rat brain provides a mechanism by which this morphogenic hormone can influence neuronal migration independent of the need for altered gene transcription. Furthermore, these data suggest a prominent role for rT(3) during brain development.

Comparative analysis of thyroxine distribution in ascidian larvae

The ascidian endostyle is a mucus-secreting pharyngeal organ, it has iodine-concentrating activity and the biosynthesis of thyroid hormones has been well documented. According to our recent findings, ascidians possess thyroid hormones, which are localized in mesenchymal cells. We have studied the presence and localization of L: -thyroxine (T(4)) in Ascidia malaca (Traustedt), Ascidiella aspersa (Müller), Phallusia mamillata (Cuvier) and Ciona intestinalis (Linnaeus) larvae and its involvement in metamorphosis. In vivo treatment of swimming larvae with exogenous T(4) and thiourea (a thyroid hormone synthesis inhibitor), demonstrate the presence of T4 during larval development. These results were confirmed by in vitro experiments utilizing dot blotting, radioimmunoassay and immunoperoxidase staining. The hormone was localized in mesenchymal cells of all four ascidians, spread out in the body cavity, under the adhesive papillae and around the intestine. The presence of TH in mesenchymal cells could be related to blood cells, musculature and heart tissue differentiation. The results suggest that this hormone could be involved in the control of metamorphosis.

Thyroid status, but not insulin status, affects expression of avian uncoupling protein mRNA in chicken

The aim of this study was to investigate the hormonal regulation of the avian homolog of mammalian uncoupling protein (avUCP) by studying the impact of thyroid hormones and insulin on avUCP mRNA expression in chickens (Gallus gallus). For 3 wk, chicks received either a standard diet (control group), or a standard diet supplemented with triiodothyronine (T(3); T3 group) or with the thyroid gland inhibitor methimazole (MMI group). A fourth group received injections of the deiodinase inhibitor iopanoic acid (IOP group). During the 4th wk of age, all animals received two daily injections of either human insulin or saline solution. The results indicate a twofold overexpression of avUCP mRNA in gastrocnemius muscle of T3 birds and a clear downregulation (-74%) in MMI chickens compared with control chickens. Insulin injections had no significant effect on avUCP mRNA expression in chickens. This study describes for the first time induction of avUCP mRNA expression by the thermogenic hormone T(3) in chickens and supports a possible involvement of avUCP in avian thermogenesis.

Cold-induced enhancement of avian uncoupling protein expression, heat production, and triiodothyronine concentrations in broiler chicks

The relationships among avian uncoupling protein (avUCP) mRNA expression, heat production, and thyroid hormone metabolism were investigated in 7-14-day-old broiler chicks (Gallus gallus) exposed to a low temperature (cold-exposed chicks, CE) or a thermoneutral temperature (TN). After 7 days of exposure, CE chicks exhibited higher heat production (+83%, P<0.01), avUCP mRNA expression (+20%, P<0.01), and circulating triiodothyronine (T(3)) levels (+104%, P=0.07) for non-statistically different body weights and feed intake between 3 and 7 days of exposure as compared to TN chicks. Plasma thyroxine (T(4)) concentration was clearly decreased in CE chicks (-33%, P=0.06). The lower hepatic inner-ring deiodination activity (-47%) and the higher renal outer-ring deiodination activity (+75%) measured in CE compared to TN chicks could partly account for their higher plasma T(3) concentrations. This study describes for the first time the induction of avUCP mRNA expression by low temperature in chickens, as it has been previously shown in ducklings, and supports the possible involvement of avUCP in avian thermogenesis.

Presence of thyroid hormones in ascidian larvae and their involvement in metamorphosis

In this study we investigated the presence and localization of thyroxine in Ciona intestinalis larvae and its involvement in metamorphosis. To date, the mechanisms regulating the metamorphosis of ascidians remain largely unknown. In vivo treatment of swimming larvae with exogenous L-thyroxine and thiourea, and in vitro experiments utilizing high performance liquid chromatography, radioimmunoassay, and immunoperoxidase staining demonstrate the presence of thyroxine at the larval stage. This suggests that this hormone may participate in the control of metamorphosis and thus play a different role from that observed in adults.

Revised T3 uptake and T4-to-T3 conversion in brain and cerebellum of 10-day-old rats: a compartment analysis

The peripheral and cerebral metabolism of thyroid hormones in 10-day-old rats was evaluated by measuring the kinetics of thyroxine (T4) and 3,5,3'-triiodothyronine (T3) fluxes. Labeled iodo-compounds were measured in the plasma, cerebellum and brain (without cerebellum) for 24 hours after the intravenous injection of [125I]T4 plus [131I]T3. Data were interpreted by compartment analysis. T4 was produced at 8.93 pmol x h(-1) and T3 at 2.26 pmol x h(-1) for 22.7 g body weight. The T4 and T3 distribution volumes were 4.26 and 22.7 ml, whereas the extra-cellular fluid volume was 9.42 ml. T4 was therefore considered to be mostly extra-cellular and T3 mostly intracellular. This was confirmed in the brain and cerebellum, where the extra-cellular fluid (ECF) fraction was 0.021 ml/g organ and the tissue-to-plasma ratio of labeled and endogenous hormones was 0.54-6.54 ml plasma/g tissue for T3 and 0.048-0.136 ml plasma/g tissue for T4. The T3 in the brain and cerebellum was distributed in several pools. The first, representing 11% of the cerebellum and 8% of the brain (without cerebellum) T3, was quickly exchanged with circulating T3. The second pool, derived from the local T4 5'-deiodination, represented 48% of the cerebellum and 94% of the brain (without cerebellum) hormone; a possible third pool (41% of the hormonal content) in the cerebellum appeared to be unlabeled by radioactive T3, and motionless. The in vivo T4 to T3 conversion, as a function of weight, accounted for 21% of cerebellum needs and 43% of brain needs. The rest was provided by T3 uptake.

Influence of imipramine on the hypothalamic/pituitary/thyroid axis of the rat

The effects of the tricyclic antidepressant drug imipramine at different levels of the hypothalamic/pituitary/thyroid axis were investigated in the rat. Intraperitoneal (IP) treatment for 14 days with imipramine at 10 mg/kg, but not 2 mg/kg, reduced serum total thyroxine (T4) and triiodothyronine (T3). A similar decrease in serum total T4 was observed in thyroidectomized T4-treated rats, suggesting that imipramine treatment enhances T4 clearance instead of reducing T4 secretion. There were no parallel decreases in serum free T4 and T3 concentrations, due to the simultaneous increase in the free fractions of both T4 and T3 following imipramine treatment. In vitro experiments using equilibrium dialysis indicated that neither imipramine nor its metabolite desipramine directly influenced the binding of T4 or T3 to their transport proteins following addition to normal serum, suggesting an indirect effect of imipramine or desipramine on free hormone concentrations in vivo. Concentrations of T4 and T3 in the brain, liver, and heart were unaffected by imipramine treatment, suggesting that the drug did not affect cellular uptake and metabolism of T4 and T3. Serum concentrations of thyrotropin (TSH) were unaffected by imipramine pretreatment at either dose level, compatible with the fact that serum free T4 and T3 concentrations were not reduced. Moreover, there was no difference in thyrotrope responsiveness to stimulation by TSH-releasing hormone (TRH) and to inhibition by T4 and T3 in rat anterior pituitary cells cultured ex vivo for 18 hours from control and imipramine-treated rats. Furthermore, in vitro exposure of cultured rat anterior pituitary cells to imipramine and desipramine indicated that both agents decreased TSH secretion only at concentrations greater than 10(-6) mol/L. These concentrations of imipramine and desipramine in the culture medium would exceed the free concentrations of these drugs seen in vivo therapeutically. In addition, no direct effects of 10(-6) mol/L imipramine or desipramine on the TSH response to TRH or to T3 were observed in vitro in cultured pituitary cells. A potential indirect effect of imipramine or desipramine on TSH secretion via altered hypothalamic control of thyrotropes does not seem likely, due to the lack of effect of imipramine treatment on serum TSH concentrations in imipramine-treated rats. In conclusion, imipramine treatment reduces serum total T4 and T3 in the rat, with enhanced clearance being the most likely explanation for the effect on T4. There was no evidence for altered tissue T4 or T3 concentrations or for altered thyrotrope function. The enhanced T4 clearance may explain the reduction in total T4 reported for imipramine-treated depressed patients. However, the effects of imipramine treatment on the transport of thyroid hormones in plasma need to be examined in more detail in patients, since interspecies differences in the nature of the transport proteins preclude extrapolation of the present results from the rat.

Immunohistochemical mapping of brain triiodothyronine reveals prominent localization in central noradrenergic systems

Many lines of evidence support a close association between thyroid hormones and noradrenergic systems in peripheral tissues. However, there is little certainty regarding interactions of the two systems in brain. We now report that triiodothyronine is concentrated in both nuclei and projection sites of central noradrenergic systems. Immunohistochemical mapping of the hormone revealed the following: (1) Locus coeruleus and all other noradrenergic cell groups identified were the most prominently labeled neural centers in the brain. (2) The hormone was also concentrated in the widely dispersed targets of noradrenergic projections. (3) Triiodothyronine labeling in noradrenergic target cells was most prominent over the cell nuclei, indicating that the hormone was bound to its receptors. Therefore, targets of noradrenergic innervation should be responsive to triiodothyronine. (4) Unlike that in noradrenergic target cells, triiodothyronine staining was decidedly perikaryal in locus coeruleus (A-6) and the other A-1 to A-7 cell groups; the staining pattern in locus coeruleus cytosol and processes was heavy, clumped and similar to that seen in contiguous sections immunostained for tyrosine hydroxylase. Results of radio-immunoassay, immunoabsorption and pharmacological tests demonstrated the specificity of the antibody for triiodothyronine and ruled against cross-reactivity with norepinephrine or its metabolites as the basis for the staining reactions. Although other possibilities consistent with these new observations are given consideration, it appears that the structure and activity of central noradrenergic systems may be major determinants of triiodothyronine distribution patterns and actions in brain. If the noradrenergic system processes both triiodothyronine and norepinephrine and conducts them both to nerve cell groups receiving its terminal arborizations, specific postsynaptic receptors would be available for transduction of both sets of messages. The evidence provides a morphological basis for earlier proposals that triiodothyronine may play a neuromodulatory or neurotransmitter role in the adrenergic nervous system.

Desmethylimipramine, a potent inhibitor of synaptosomal norepinephrine uptake, has diverse effects on thyroid hormone processing in rat brain. II. Effect on in vivo 5'-deiodination of [125I]thyroxine

We have studied the effects of desmethylimipramine (DMI), a tricyclic antidepressant, on thyroid hormone (TH) handling in rat brain in an effort to discover a pharmacological basis for reported interactions between TH, affective disorders and psychotropic drugs. An acute dose of DMI has been used in order to determine the primary effects of the drug in brain without perturbations from secondary effects. Recently we have reported that a single dose of DMI significantly decreases brain uptake of both [125I]thyroxine (T4) and [125I]3,3',5-triiodothyronine (T3) across the spectrum of thyroid states from hypothyroid (HYPO) to euthyroid (EU) to T4-induced hyperthyroid (HYPER). To investigate further the effects of DMI on brain processing of TH, we have measured effects of the drug on in vivo rates of T4 to T3 conversion in a series of experiments in which DMI (25 mg/kg) was given to HYPO, EU and HYPER male rats in conjunction with i.v. [125I]T4. Decreased in vivo conversion ratios (T3/T4 ratios) suggest that acute DMI treatment causes a significant decrease in 5'-deiodinase activity in balance of brain (but not cerebellum) in all DMI treated rats as compared to their saline treated controls (ANOVA, P < 0.0001). For assurance that reduced T3/T4 in DMI treated rat brain is not the result of DMI enhancement of 5-deiodination of T3 or T4, the effect of DMI on concentrations of labeled I-, rT3, and T2 (3,3'- and 3',5'-) was also observed. In no case was there a significant increase in any metabolite in DMI treated rats for any tissue studied.(ABSTRACT TRUNCATED AT 250 WORDS)

Desmethylimipramine, a potent inhibitor of synaptosomal norepinephrine uptake, has diverse effects on thyroid hormone processing in rat brain. I. Effects on in vivo uptake of 125I-labeled thyroid hormones in rat brain

Several lines of evidence point to an interaction between amine uptake inhibitors (tricyclic antidepressants) and thyroid hormones. To examine this issue under conditions which would minimize secondary effects of drug treatment, desmethylimipramine (DMI), a highly specific norepinephrine uptake inhibitor, was given acutely as a single i.p. dose one hour before i.v. [125I]triiodothyronine (T3*) or [125I]thyroxine (T4*). Tissues were analysed after rat decapitation at 3, 5, 10, and 20 min intervals thereafter. DMI had a small but significant inhibitory effect on the brain uptake of both T3* (7.4%) and T4* (19%) over their respective 20-min time courses as indicated by two-way ANOVA. To examine the drug response further and to determine the effect of thyroid status on the response, hypothyroid (HYPO) and T4-induced hyperthyroid (HYPER) rats, were given i.v. T3* and, 5 min later, i.p. DMI or saline. They were killed 3 h later and tissue analysed. Because DMI effects on T4* uptake could not be evaluated over a 3 h period without blocking T4* to T3* conversion, sodium ipodate (60 mg/kg) was given in 2 doses before i.v. T4*. Under these conditions, DMI significantly reduced brain concentrations of the administered T3* and T4* in HYPO (15% and 19%) and in HYPER rats (13% and 25%). These results suggest that, as it does in the case of norepinephrine, DMI blocks the uptake site for T3 and T4 in rat brain. No information is available regarding the relationship, if any, between the thyroid hormone and norepinephrine uptake sites.

Reduced tissue thyroid hormone levels in fatal illness

Patients with severe nonthyroidal illnesses (NTIs) frequently have decreased serum concentrations of triiodothyronine (T3) and less often of thyroxine (T4) without clear evidence of hypothyroidism. To determine whether T3 and T4 levels are also reduced in the tissues, we analyzed autopsy samples from 12 patients dying of NTI and 10 previously healthy individuals dying suddenly from trauma. Mean serum T3, T4, and free T4 index values were lower by 79%, 71%, and 49%, respectively, in the NTI group than in controls, but serum thyrotropin (TSH) values did not differ significantly. Mean T3 concentrations in cerebral cortex, hypothalamus, pituitary, liver, kidney, and lung were lower in the NTI group than in controls by 43% to 76%, but mean values in heart and skeletal muscle did not differ significantly between the groups. The mean liver T4 concentration was 66% lower in the NTI group, but mean T4 concentrations in the cerebral cortex were similar in the two groups. These results indicate that many tissues may be deficient in thyroid hormones in patients with fatal NTI, although the severity of the reduction in thyroid hormone concentrations may vary from one organ to another.

Corticotropin-releasing factor stimulates metamorphosis and increases thyroid hormone concentration in prometamorphic Rana perezi larvae

Attempts to identify a hypothalamic molecule that stimulates thyrotropin (TSH) secretion from amphibian pituitary have been unsuccessful to date. The effects of mammalian (ovine and human) corticotropin-releasing factor (CRF) on the thyroid function of prometamorphic (Taylor & Kollros stages XI-XVII) (Taylor and Kollros, 1946) Rana perezi larvae were studied. Chronic treatments with both ovine and human CRF (oCRF, hCRF) stimulated metamorphosis while delaying larval growth. Chronic hCRF (1 microgram) administration induced 3.2- and 5.3-fold increases in whole body concentration of thyroxine (T4) and triiodothyronine (T3), respectively. In contrast, the 0.5-microgram dose of hCRF stimulated a significant (3.4-fold) increase in whole body concentration of T4 but not of T3. Histological studies of the thyroid gland revealed a 22% increase in the number of follicles per section as a result of the chronic treatment with oCRF (1 microgram). Acute oCRF (2 micrograms) treatment induced a significant increase in T4 concentration at 4 hr (1.3-fold) and 8 hr (2.3-fold) postinjection. T3 concentration was not altered. These results support previous reports and lead us to conclude that a CRF-like peptide, and not TRH, is involved in the regulation of thyroid activity in anuran amphibians during metamorphosis.

Method for the quantitation of iodothyronines in body tissues and fluids using high-performance liquid chromatography

The separation and quantitation of iodotyrosines and iodothyronines [3-monoiodo-L-tyrosine, 3,5-diiodo-L-tyrosine, 3,5-, 3,3' and 3',5'-diiodo-L-tyronines, 3,5,3'-triiodo-L-thyronine (T3), reverse 3,3',5'-triiodo-L-thyronine and 3,3',5,5'-tetraiodo-L-thyronine (T4)] from animal tissues (brain, liver and serum) by a new high-performance liquid chromatographic (HPLC) method is described. Rats were infused with iso-osmotic sodium chloride containing 100 microM phloretin to block deiodination. The tissues were extracted using differential pH values to separate other amines from the amine containing iodothyroid hormones. Aliquots of tissue extracts (25-100 microliters) were reacted overnight with 5-dimethylaminonaphthalene-1-sulfonyl chloride and their iodotyrosine and iodothyronine content determined by HPLC utilizing fluorimetric detection. Resolution of the individual compound peaks was achieved by gradient elution with a 3.0 mM H3PO4 buffer. Greater sensitivity has been achieved (less than 1.0 pmol/g) utilizing fluorescence rather than ultraviolet absorbance for the quantitation of these iodinated compounds. The method is superior also to other methods in that recoveries, based on those of 125I-labelled T4 and T3, were 89-97%.

Maintenance of thyroid hormone production during exercise-induced weight loss

Calorie restriction reduces thyroxine (T4) and 3,5,3'-triiodothyronine (T3) production, but the effects of exercise-induced weight loss on thyroid hormone metabolism in rodents are unclear. We studied the effects of chronic exercise on T4 and T3 metabolism comparing exercising (exercise) rats pair fed to sedentary (control) rodents and to weight-matched underfed sedentary animals (underfed; caloric intake 75% of ad libitum-fed controls). The exercise group utilized voluntary running wheels (28 days), and thyroid hormone metabolism was assessed using a three-compartment kinetics model. The exercise and underfed groups were equivalent in weight, but protein mass was greater in the exercise vs. underfed groups (30.4 +/- 0.5 vs. 27.9 +/- 0.5 g; P less than 0.05). During exercise, the T4 plasma clearance rate (PCR) was decreased (-39.2%; P less than 0.01) and the T4 concentration in serum was increased (48.6%; P less than 0.01), resulting in an unchanged T4 plasma appearance rate (PAR) vs. the control group. The decrease in T4 PCR in the exercise group was associated with a lower transport rate of T4 out of the slow pool (P less than 0.01). In the underfed group there was a reduction in both T4 serum concentration and PAR (-36%; P less than 0.01) compared with the control group, which was associated with a decrease in the volume of distribution (-25%; P less than 0.01). T3 PAR decreased 38.7% (P less than 0.01) during underfeeding but only 16.9% (P = not significant) during exercise vs. the control group.(ABSTRACT TRUNCATED AT 250 WORDS)

Thyroid hormones in tissues from human embryos and fetuses

This study was intended to quantify T3 and T4 in various human tissues at different stages of gestation as a contribute in the evaluation of the role of thyroid hormones in fetal development, particularly before the maturation of fetal thyroid function. Moreover, for a better comprehension of the influence of thyroid hormone status in tissues, the study was extended to adults. Embryonic specimens were obtained from voluntary abortions between 6 and 12 weeks of gestation, fetal and neonatal specimens from fetuses and neonates between 15 and 36 weeks of gestation after spontaneous abortion or stillbirth, and adult specimens from men (age range: 45-65 years) after death for cardiovascular diseases. Thyroid hormones were measured by the method of Gordon and coworkers. In embryos T3 and T4 were measured in limbs, carcasses, brain and liver: considering all values measured in the period 9-12 weeks, a mean concentration of 0.11 ng/g for T3 and 1.28 ng/g for T4 was obtained. In pooled limbs of 6-8 weeks T3 was barely measurable (0.01 ng/g). In the carcasses there was an increase in T3 and T4 concentrations of 40 and 20 times respectively from the 9th to the 12th week, when thyroid follicles organization takes place. In fetuses and adults T3 and T4 were measured in brain, heart, kidney, liver, lung, skeletal muscle and skin (mean concentrations: 0.86 ng/g for T3 and 7.44 ng/g for T4 in fetuses and neonates; 1.36 ng/g for T3 and 12.75 ng/g for T4 in adults). Hormones concentration increased with gestational age; the T3/T4 ratio increased until 22-24 weeks, when the prevalent increment in T4 occurs. T3 concentration up to 30 weeks was generally higher in tissues than in cord serum of the corresponding age. During the last month of gestation T3 increment was faster in serum. T4 level was always predominant in serum. In conclusion, T3 and T4 have been detected in the limbs of embryos before the onset of thyroid hormone secretion. Concentrations were 1/150 and 1/70, of the normal maternal blood values respectively. It is conceivable that these hormones are of maternal origin, and the question of whether such small quantities may play a role in fetal development is open.

Determination of L-thyroxine in reference serum preparations as the o-phthalaldehyde-N-acetylcysteine derivative by reversed-phase liquid chromatography with electrochemical detection

A simple procedure for the assay of L-thyroxine in serum preparations with D-thyroxine as internal standard is described. The L-thyroxine is extracted with acetonitrile, fractionated on a reversed-phase silica cartridge and analysed by reversed-phase high-performance liquid chromatography of the o-phthalaldehyde-N-acetyl-L-cysteine derivative. This derivative is not fluorescent, but may be detected with suitable sensitivity and selectivity with an electrochemical detector.

Presence of thyroxine in eggs and changes in its content during early development of chum salmon, Oncorhynchus keta

In order to examine the role of thyroid hormones during salmonid development, techniques were developed for quantitative extraction of thyroxine from eggs, whole embryos, and alevins of chum salmon (Oncorhynchus keta) at various stages of development. Frozen eggs, embryos, alevins, or fry were homogenized in ice-cold methanol. The homogenate was centrifuged, and the supernatant was washed with a mixture of chloroform and 0.05% CaCl2. The aqueous layer was lyophilized, and the residue was redissolved in barbital buffer for thyroxine radioimmunoassay (RIA). Serial dilutions of the egg or tissue extracts gave inhibition slopes that were parallel to that of the thyroxine standard in the RIA. Immunoreactivity of the extracts coeluted with thyroxine standard in reverse-phase HPLC on an ODS column. Recovery of thyroxine from egg and tissue extracts was estimated from the recovery of 125I-labeled thyroxine added to the initial homogenates. Thyroxine content of eggs just after fertilization was 4-5 ng/egg, and this level was maintained until hatching. A decrease in thyroxine content was seen during yolk absorption. Total thyroxine increased to about 10 ng/fish, a level higher than that in the unfertilized egg, at the time of complete yolk absorption, and decreased within 10 days to a low level of 1 ng/fish. These findings are discussed in relation to the role of maternal thyroid hormones during early development and also to the onset of larval thyroid function.

[125I] triiodothyronine in the rat brain: evidence for neural localization and axonal transport derived from thaw-mount film autoradiography

Previous thaw-mount light microscopic autoradiographic studies have shown that intravenously administered [125I] triiodothyronine is saturably concentrated and retained for at least 10 hours in discrete neural systems in the rat brain. To survey the brain more completely and to gain information about the time course of labeling, serial thaw-mount film autoradiograms were prepared from rat brains obtained at intervals through 48 hours after intravenous injection of high specific activity [125I] triiodothyronine. Parallel biochemical studies of whole brain homogenate extracts revealed that, at all time intervals, the label in the brain was mainly due to triiodothyronine itself (80%), or other organic iodocompounds (15%), but probably not due to free [125I] iodide (3%), which is rapidly transported out of the brain. The highly reproducible, well-defined labeling patterns seen on film indicated a widespread but selective localization of the hormone. At early times after intravenous injection of [125I] triiodothyronine, label was nonuniformly and prominently concentrated in selected regions of gray matter; evidence for saturability of hormone processing was obtained in competition studies with unlabeled triiodothyronine. Discrete labeling of fiber tracts (usually after 10 hours) left some regions of white matter conspicuously unlabeled. At 48 hours, many originally labeled gray regions showed markedly diminished or virtually complete loss of radioactivity, whereas others became newly or more prominently labeled. At that time, certain fiber tracts were also conspicuously labeled. The observed changing profiles of regional labeling over time are best explained by movement of the hormone from original sites of saturable incorporation in specific nuclei, to terminal fields, through the mechanism of axonal transport.

Iodothyronine homeostasis in rat brain during hypo- and hyperthyroidism

Thyroid hormones are concentrated, retained, and metabolized in discrete neural systems in rat brain. To determine how iodothyronine requirements of brain compare with those of other thyroid hormone-dependent tissues, we measured effects of chronic thyroid hormone deficiency or excess on brain iodothyronine economy and particularly on the intracerebral rate of triiodothyronine formation from thyroxine. The results demonstrate that despite extremes of thyroxine availability, brain thyroxine and triiodothyronine concentrations and brain triiodothyronine production and turnover rates are kept within narrow limits. Adjustments in the activity of both brain and liver help to maintain these relatively stable conditions. Following thyroidectomy, fractional rates of triiodothyronine formation from thyroxine decrease to low levels in liver, whereas they increase markedly in brain; exactly the opposite direction of change occurs in brain and liver during hyperthyroidism. These responses suggest that brain iodothyronine homeostasis is important for the function of the whole organism. Because signs of nervous system dysfunction develop in hypothyroid and hyperthyroid individuals, it is possible that even relatively small deviations of brain iodocompound economy can produce significant changes in behavior and autonomic nervous system function.