The Effects of Perinatal PCB Exposure and Hypothyroidism on Motor Development in the Sprague-Dawley Rat

Hiler, Katie Ann

29 July 2009

No description available.

Biology

polychlorinated biphenyls

thyroid hormones

PCB

motor function

motor development

tyrosine hydroxylase

Effects of ammonium perchlorate exposure on the thyroid function and the expression of thyroid-responsive genes in Japanese quail embryos and post hatch chicks

Chen, Yu

05 August 2008

Perchlorate ion interferes with thyroid function by competitively inhibiting the sodium-iodide symporter, thus blocking iodide uptake into the thyroid gland. In this study, the effect of perchlorate exposure on thyroid function and thyroid-responsive gene expression were examined in (1) embryos from eggs laid by perchlorate-treated Japanese quail hens and (2) perchlorate-treated young Japanese quail. I hypothesized that perchlorate exposure would decrease thyroid function and that the consequent hypothyroidism would alter the expression of thyroid sensitive genes. Laying Japanese quail hens were treated with 2000 mg/l and 4000 mg/l ammonium perchlorate in drinking water. Eggs from these hens were incubated. Embryos, exposed to perchlorate in the egg, were sacrificed at day 14 of the 16.5 day incubation period. Japanese quail chicks, 4-5 days old, were treated with 2000 mg/l ammonium perchlorate in drinking water for 2 and 7.5 weeks. Thyroid status was evaluated by measuring plasma thyroid hormone concentrations, thyroid gland weight and thyroidal thyroid hormone storage. Expression of thyroid-responsive genes was evaluated by measuring the mRNA levels of Type 2 deiodinase (D2) in the brain and liver, RC3/neurogranin mRNA level in the brain and Spot 14 mRNA level in the liver. Maternal perchlorate exposure led to embryonic hypothyroidism, demonstrated by thyroid hypertrophy and very low embryonic thyroidal TH storage. Embryonic hypothyroidism decreased body growth and increased D2 mRNA level in the liver (a presumed compensatory response to hypothyroidism) but did not affect the mRNA levels of D2 and RC3 in the brain. Spot 14 mRNA was not detected in embryonic liver. In the second part of the study, quail chicks showed early signs of hypothyroidism after two weeks of 2000 mg/l ammonium perchlorate exposure; plasma concentration and thyroid gland stores of both T4 and T3 were significantly decreased. After 7.5 weeks of perchlorate exposure, all thyroid variables measured indicated that the chicks had become overtly hypothyroid. D2 mRNA level was increased, a compensatory response to hypothyroidism, and spot 14 mRNA level was decreased, a substrate-driven response in the liver of quail chicks after two weeks of perchlorate exposure. However, no difference was observed in the mRNA levels of D2 and spot 14 in the liver after 7.5 weeks of perchlorate exposure, suggesting there was some adaptation to the hypothyroid condition. The mRNA level of D2 and RC3 in the brain was not affected by perchlorate-induced hypothyroidism in quail chicks after either 2 or 7.5 weeks of perchlorate exposure. As in the embryos, this suggests the brain of chicks was "protected" from the hypothyroid body conditions. / Ph. D.

Type 2 deiodinase

ammonium perchlorate

Japanese quail

Spot 14

RC3/neurogranin

thyroid hormones

thyroid disruption

Uridinediphosphate-glucuronosyltransferase (UDP-GT) Ontogeny and PCB Effects in Galliform Birds

McCleary, Ryan J. R.

06 December 2001

Hepatic UDP-GTs are partly responsible for metabolism of the thyroid hormone, thyroxine (T4), in mammals, but little is known of UDP-GT activity in birds. To determine the ontogenic pattern of UDP-GT activity in precocial birds, we measured activity in Japanese quail (Coturnix japonica) liver at days 12 and 14 of the 16.5-day incubation, 3 perihatch stages and <1, 1, 4, 6, 7, 20 and 42 days posthatch. We used an enzymatic reaction with para-nitrophenol (pNP) as substrate that was validated for quail tissue. The pattern of UDP-GT development included low embryonic activity, increased activity beginning in the perihatch period, a peak in activity at day 4 posthatch and a return to lower activity levels from day 6 to adults. The profile of UDP-GT activity, in relation to the ontogeny of circulating T4 and triiodothyronine (T3) in quail, is consistent with UDP-GT playing a role in regulating circulating T4 and with the perihatch peak in T3 stimulating the posthatch peak in UDP-GT activity. To examine the effects of polychlorinated biphenyls (PCBs) on UDP-GT in developing precocial birds, we dosed chicken (Gallus domesticus) eggs with concentrations of PCB 126 from 0 to 0.80 ng/g egg (in sunflower oil) prior to incubation. Tissues were sampled at day 20 of the 21-day incubation and assayed for plasma hormones and UDP-GT activity. Eggs also were dosed with 0 or 0.25 ng PCB 126/g egg or with 0 or 0.64 ng/g egg of the coplanar PCB 77, allowed to hatch, and sampled at 42 days posthatch. There was no consistent pattern of altered thyroid hormones or UDP-GT activity in developing chickens exposed to either of these coplanar PCBs although previous studies indicated developmental alterations from exposure to the higher doses. / Master of Science

thyroid hormones

PCBs

Japanese quail

avian development

Halogen Bonding in the Structure and Biomimetic Dehalogenation of Thyroid Hormones and Halogenated Nucleosides

Mondal, Santanu

January 2016

Thyroid hormones, which are secreted by the thyroid gland, are one of the most important halogenated compounds in the body. Thyroid hormones control almost every processes in the body including growth, body temperature, protein synthesis, carbohydrate and fat metabolism, heart rate, and cardiovascular, renal and brain function. Thyroid gland secretes L-thyroxine or 3,3',5,5'-tetraiodothyronine (T4) as a prohormone. While the biologically active hormone 3,3',5-triiodothyronine (T3) is produced by selective phenolic ring deiodination of T4, selective tyrosyl ring deiodination of T4 produces a biologically less active metabolite 3,3',5'-triiodothyronine (rT3). Tyrosyl and phenolic ring deiodination of T3 and rT3, respectively, also produces a biologically inactive metabolite 3,3'-diiodothyronine (3,3'-T2). Regioselective deiodinations of thyroid hormones are catalysed by three isoforms of a selenoenzyme iodothyronine deiodinase (DIO1, DIO2, DIO3). DIO1 can remove iodine from both the tyrosyl and phenolic rings of thyroid hormones, whereas DIO2 and DIO3 are selective towards phenolic and tyrosyl ring, respectively. Although the Figure 1. (A) Deiodination of thyroid hormones by iodothyronine deiodinases (DIOs) (A) and naphthyl-based selenium and/or sulphur compounds (B). mystery behind the origin of regioselectivity of deiodination by DIOs remains unsolved, formation of halogen bonding between selenium in the active site of DIOs and iodine of thyroid hormones has been widely accepted as the mechanism of deiodination. Halogen bonding, a noncovalent interaction between halogen and an electron donor such as nitrogen, oxygen, sulphur, selenium etc., elongates the C-I bond and impart a carbanionic character on the carbon atom that gets protonated after the removal of iodide. Apart from the deiodination, thyroid hormones also undergo decarboxylation, oxidative deamination, sulphate-conjugation to form iodothyronamines, iodothyroaetic acids and sulphated thyroid hormones, respectively. Figure 2. (A) Proposed mechanism of deiodination of thyroid hormones by deiodinase mimics. (B) Halogenation of uracil- and cytosine-containing nucleosides by hypohalous acid (HOX). Recently, naphthyl-based selenium/sulphur-containing compounds, such as compound 1 (Figure 1B), have been reported to mediate the selective tyrosyl ring deiodination of T4 and T3 to form rT3 and 3,3'-T2, respectively. Interestingly, replacement of the selenol moiety in compound 1 with a thiol decreases the activity, whereas replacement of the thiol moiety with another selenol dramatically increases the deiodination activity. Based on the detailed experimental and theoretical investigations, a mechanism involving the Se···I halogen bonding was proposed (Figure 2A). In addition to the halogen bonding between selenium and iodine atom, chalcogen bonding between two nearby chalcogen atoms was also shown to be important for the deiodination activity. Another important class of halogenated compounds in the body are the halogenated nucleosides. Myeloperoxidase and eosinophil peroxidase are heme-containing enzymes, which can convert halide ions (X¯) into a toxic reactive halogen species hypohalous acid (HOX) in presence of hydrogen peroxide (H2O2). Uracil- and cytosine-containing nucleosides are known to undergo halogenation at the 5-position of the nucleobase to form the halogenated nucleosides (Figure 2B). Interestingly, halogenated nucleosides such as 5-halo-2'-deoxyuridine are known to be incorporated in the DNA of dividing cells essentially substituting for thymidine. Incorporation of halogenated nucleosides into the DNA leads to mutagenesis, carcinogenesis and loss of genome integrity. Thymidylate synthase (TSase), the key enzyme involved in the biosynthesis of 2'-deoxythmidine-5'-monophosphate (dTMP) from 2'-deoxyuridine-5'-monophosphate (dUMP), can catalyse the dehalogenation of halogenated nucleotides in presence of external thiols. This thesis consists of five chapters. The first chapter provides a general introduction to halogen bonding, thyroid hormones and halogenated nucleosides. This chapter also briefly describes the halogen bond-mediated biochemical and biomimetic deiodinations of thyroid hormones by iodothyronine deiodinases and naphthyl-based organoselenium compounds. Dehalogenation of halogenated nucleotides by thymidylate synthase and thiol-based small molecules has also been discussed in this chapter. The second chapter of this thesis contains the regioselective deiodination of iodothyronamines (TAMs) by deiodinases mimics. TAMs are the endogenous metabolites produced by the decarboxylation of β-alanine side chain of thyroid hormones (THs). 3,3',5-triiodothyronamine (T3AM) and 3,5-diiodothyronamine (3,5-T2AM) undergoes selective tyrosyl ring deiodination by deiodinase mimics to form 3,3'-diiodothyronamine (3,3'-T2AM) and 3-iodothyronamine (3-T1AM), respectively. Interestingly, when the initial rates of deiodinations of T3 and T3AM were compared, deiodination of T3 was found to be several fold faster than that of T3AM under identical reaction conditions. To understand the ability of the iodine atoms to form Figure 3. (A) HPLC chromatogram of deiodination of T3. (B) Proposed mode of interaction of dimeric T3 and monomeric T3AM with organoselenium compounds. halogen bonding, a model selenolate (MeSe¯) was optimized with the T3 and T3AM. Although both T3 and T3AM forms the expected Se···I halogen bonding with MeSe¯, the strength of halogen bonding was found to be less for T3AM than T3. Furthermore, detailed kinetic and spectroscopic studies indicate that T3 and T3AM exist as dimeric and monomeric species in solution. The dimerization of T3 in solution was shown to have remarkable impact on the activation energy and pre-exponential factor of the deiodination reactions. Single crystal X-Ray crystallography and theoretical calculations indicated that in addition to Se···I halogen bonding, I···I halogen bonding may play an important role in the deodination of thyroid hormones by deiodinase mimics. Furthermore, the presence of heteroatoms such as nitrogen, oxygen and sulphur in the close proximity of one of the selenium atoms of deiodinase mimics was shown to have significant effect on the rate of deiodination reactions. The third chapter of the thesis focusses on the conformational polymorphism and conformation-dependent halogen bonding of L-thyroxine. Synthetic version of L-thyroxine (T4) is a life-saver for millions of people who are suffering from hypothyroidism, a thyroidal disorder recognised by low levels of T4 and elevated levels of TSH in blood plasma. Synthetic version of L-thyroxine is available in the Figure 4. Ball and stick model of the single crystal X-Ray structure of the conformational polymorphs of L-thyroxine. Form I and Form II was exclusively crystallized from methanol and acetonitrile, respectively. Water molecules are omitted for clarity. market with various brand names. However, adverse effects have been observed in the patients when they switch their brand of thyroxine. Based on these observations, the American Thyroid Association (ATA), the Endocrine Society (TES), and the American Association of Clinical Endocrinologists (AACE) declared that the different brands of T4 are not bioequivalent, thus leading to differences in the bioavailability of the drug. We have shown that the commercially available thyroxine exists in at least two stable forms (Form I and Form II) with different three-dimensional structures (Figure 4). These two forms exhibit different intermolecular interactions in crystal packing, spectral behaviours, thermal stabilities, optical activity and very interestingly, different solubility in acidic and basic pH. At pH 4, solubility of Form I is about 42% and 45% greater than that of Form II and bulk T4, respectively, whereas at pH 9, the solubility of Form II is about 38% and 42% higher than that of Form I and bulk T4, respectively. As T4 is a narrow therapeutic index drug, these differences in solubility may have remarkable impact on the bioavailability of the drug. In addition to this, we have shown that the ability of the iodine atoms in the C-I bonds to form halogen bond with donor atoms can be altered by changing the relative orientation of tyrosyl and phenolic rings in T4. In the fourth chapter, the three-dimensional structures and conformations of thyroid hormones (THs) and iodothyronamines (TAMs) are discussed. TAMs, the endogenous decarboxylated metabolites of THs, exhibit different binding affinities to the transport proteins and iodothyronine deiodinases (DIOs) compared to the THs. Figure 5. Change in the structure and conformations of thyroid hormones and iodothyronamines with the decarboxylation of amino acid side chain and deiodination of phenolic and tyrosyl ring. Furthermore, the substrate specificities of DIOs have been found to be dependent on the position of iodine atoms on the phenolic and tyrosyl ring of TAMs and THs. Single crystal X-ray structures of TAMs indicate that decarboxylation of amino acid side chain of THs induces significant changes in the structure and conformation. Furthermore, the positional isomers of THs and TAMs exhibit remarkably different conformations, which may have significant effect on the binding of these metabolites to the active site of DIOs. In addition to the structure and conformations, different categories of the intermolecular halogen···halogen (X···X) interactions in the crystal packing of THs and TAMs have also been discussed. Natural bond orbital (NBO) analysis have been done on the halogen-bonded geometries to understand the electronic nature of these interactions. In the fifth chapter, the dehalogenation of halogenated nucleosides and nucleobases by naphthyl-based sulphur/selenium compounds is discussed. Purine and pyrimidine nucleosides are halogenated at various positions of the aromatic ring by different peroxidases such as myeloperoxidase and eosinophil peroxidase present in the white blood cells. Incorporation of the halogenated nucleosides into the DNA of replicating cells leads to DNA-strand breaks, mutagenesis, carcinogenesis and loss of Figure 6. (A) Dehalogenation of halogenated nucleosides. Effect of base-pairing wih adenine and guanine on the deiodination of IU (B) and debromination of BrU (C) by compound 2. genome integrity. We have shown that the naphthalene-based organoselenium compounds such as compound 2 can mediate the dehalogenation of 5-iodo-2'-deoxyuridine (5-IdUd) and 5-bromo-2'-deoxyuridine (5-BrdUd) to produce 2'-deoxyuridine (dUd) (Figure 6A). The deiodination of 5-IdUd was found to be faster than the debromination of 5-BrdUd by compound 2. The mechanism of dehalogenation of halogenated nucleosides by compound 2 was found to be dependent on the nature of halogen. While the deiodination of 5-IdUd by compound 2 follow halogen bond-mediated pathway like thyroid hormones, debromination of 5-BrdUd follow a Michael addition-elimination pathway. Similar results were obtained when 5-iodo-2'-deoxycytidine (5-IdCd) or 5-bromo-2'-deoxycytidine (5-BrdCd) was used as substrate for dehalogenation reaction. Base-pairing of 5-iodouracil (IU) and 5-bromouracil (5-BrU) with adenine and guanine has a significant effect on the rate of dehalogenations of IU and BrU by compound 2 (Figure 6B and 6C).

Halogen Bonding

Dehalogenation - Thyroid Hormones

Thyroid Hormones

Halogenated Nucleosides

Organohalogen Compounds

Iodothyronine Deiodinases (DIOs)

L-thyroxine (T4)

Iodothyronamines (TAMs)

DNA-Repair Pathway

Thyroxine Polymorphs

Deiodinase Mimics

Inorganic and Physical Chemistry

Ações rápidas da triiodotironina (T3) sobre a expressão e secreção de TSH: novos mecanismos envolvidos no feedback negativo. / Rapid actions of triiodothyronine (T3) on TSH expression and secretion: new mechanisms involved in the negative feedback.

Souza, Paula Bargi de

11 March 2015

O hormônio tireotrófico (TSH) é o principal regulador da síntese e da secreção dos hormônios tireoidianos (HTs), os quais exercem um mecanismo de feedback negativo na hipófise reduzindo a síntese das cadeias beta (Tshb) e alfa (Cga) por meio de ações genômicas. Em paralelo, algumas ações dos HTs são desencadeadas na presença de inibidores da transcrição gênica e em segundos a minutos, caracterizando-se assim as ações não genômicas. O objetivo deste estudo foi avaliar as possíveis ações não genômicas do T3 sobre a expressão, processamento pós-transcricional, tradução e secreção do TSH, e a participação do cálcio e magnésio neste processo. Os resultados demonstraram que o T3, via interação com a integrina aVb3, reduz o conteúdo de mRNA de Tshb mesmo na presença de bloqueador da transcrição gênica, o comprimento da cauda poli(A), a taxa de tradução deste transcrito e a secreção por vias dependentes da integrina aVb3 e PI3K. E também aumenta a concentração intracelular de magnésio mas não altera a de cálcio. Estes dados evidenciam a existência de um mecanismo adicional e não genômico pelo qual o T3 interage com a integrina aVb3 e reduz a síntese/secreção de TSH que se soma ao já conhecido efeito de feedback negativo via controle da taxa de transcrição gênica de Tshb e Cga. / The thyrotropin (TSH) is the main regulator of thyroid hormones (HTs) synthesis and secretion, which in turn, exert a negative feedback in the pituitary gland reducing the synthesis of alpha (Cga) and beta (Tshb) TSH subunits by genomic actions. In parallel, some HTs actions are triggered in the presence of inhibitors of gene transcription and in seconds to minutes, featuring the non genomic actions of HTs. The goal of this study was to evaluate the possible non genomic actions of T3 on expression, posttranscriptional regulation, translation and secretion of TSH, as well as, the participation of calcium and magnesium on this process. The results have shown that the T3, interacts with aVb3 integrin, reduces the content of Tshb mRNA even in the presence of gene transcription inhibitor, decreases the poly(A) tail length, the translation rate of this transcript and the secretion through aVb3- and PI3K-dependent mechanisms. The T3 also increases and does not alter the intracellular concentration of magnesium and calcium, respectively. These data demonstrates the existence of an additional and non genomic mechanism by which the T3 interacts with aVb3 integrin and reduces the synthesis/secretion of TSH, in parallel to the control of Tshb and Cga gene transcription.

Ações não genômicas

Hormônio tireoidiano

Non genomic actions

Poliadenilação

Polyadenylation

Secreção

Secretion

Thyroid hormones

Thyrotroph

Thyrotropin (TSH)

Tireotrofo

Tirotrofina (TSH)

Estudo da imobilização do receptor tireoidiano humano TR&#946;1 em filmes finos nanoestruturados e aplicações em detecção de hormônios tireoidianos / Immobilization and sensing ability of human thyroid nuclear receptor in nanostructured thin films

Bendo, Luana

07 June 2010

A manipulação de materiais em escala nanométrica representa uma das fronteiras em nanociência e nanotecnologia, devido à possibilidade de controle de propriedades específicas do material. No caso de materiais biológicos, em particular, a manipulação e imobilização na forma de filmes ou camadas ultrafinas é crucial para seu emprego em dispositivos biotecnológicos. Neste trabalho, objetivou-se o estudo de detecção de diferentes hormônios tireoidianos (HTs) e análogos a partir da imobilização da região LBD do receptor de hormônio tireoidiano humano TRTR&#946;1 em um eletrodo interdigitado, para o desenvolvimento de um biossensor capacitivo. Este sistema consiste em um arranjo estrutural na forma de filme fino capaz de distinguir a interação específica receptor-ligante de outras interações possivelmente interferentes, visando a quantificação dos níveis de HTs. Para isto, a técnica de SAMs (Self-Assembled Monolayers) foi empregada, por permitir um alto controle da espessura e ordenamento molecular dos filmes, assim como a preservação das atividades das biomoléculas. Análises espectroscópicas e morfológicas foram realizadas para o estudo de adsorção das biomoléculas no filme. As interações específicas receptor-ligante foram avaliadas por meio de respostas elétricas (impedância) do biossensor contendo o TR&#946;1-LBD imobilizado em um filme orgânico ultrafino, e também por SPR (Surface Plasmon Resonance). Os resultados mostraram a capacidade dos eletrodos contendo TRTR&#946;1-LBD de detectar e diferenciar entre diferentes HTs em concentrações da ordem de nanomolar, compatível com níveis fisiológicos, evidenciando o grande potencial de aplicação para este sistema no diagnóstico e tratamento de disfunções tireoidianas. / Manipulation of materials at the nanoscale represents one of the frontiers in nanoscience and nanotechnology, mainly due to the possibility of specific controlling, improved properties, not observed if conventional bulk processing is applied. For biomolecules, in particular, processing via immobilization in the form of nanostructured films has allowed their use in biotechnological applications and devices. In this master dissertation, we aimed at investigating the immobilization of the LBD domain of human thyroid hormone receptor TRTR&#946;1 on interdigitated electrodes, to be used as capacitive biosensors for thyroid hormones (THs) and analogues detection. The nuclear receptors were immobilized via SAMs (Self-Assembled Monolayers), since this technique allows a high control of molecular order and thickness of the films, as well as the preservation of biological activities. Spectroscopic and morphological analyses were performed to investigate the adsorption of biomolecules on the nanostructured film. The interactions between receptor - ligand were also evaluated by means of electrical response (impedance) and SPR (Surface Plasmon Resonance). The bioelectrodes containing immobilized TRTR&#946;1 were capable of detecting and distinguishing among different HTs, including T3, T4, TRIAC and GC-1 at concentrations down to nanomolar, compatible with physiological levels. The latter results point to the possibility of applications of the bioelectrodes in the diagnosis and treatment of thyroid dysfunctions.

Biosensor

Biossensor

Hormônios tireoidianos

Human thyroid nuclear receptor

Imobilização

Nanomedicina

Nanomedicine

Protein immobilization

Receptor nuclear tireoidiano humano

Thyroid hormones

Avaliação dos efeitos da co-administração dos hormônios da tireoide e do carvedilol sobre o coração de ratos Wistar submetidos ao infarto agudo do miocárdio

Ortiz, Vanessa Duarte

January 2018

Introdução: Após o infarto agudo do miocárdio (IAM), o tratamento com hormônios da tireoide (HT) vem revelando efeitos cardioprotetores. Os HT, todavia, provocam uma estimulação adrenérgica, induzindo elevação da frequência cardíaca, a qual contribui para progressão da disfunção ventricular após o IAM. O betabloqueador carvedilol, entretanto, é capaz de bloquear a estimulação adrenérgica. Objetivo: Avaliar o efeito da administração conjunta dos HT e do carvedilol sobre o coração de ratos submetidos ao IAM. Nesse contexto, enfocar nos efeitos dessa coadministração sobre o remodelamento ventricular, a função cardíaca e o estresse oxidativo. Materiais e métodos: Ratos Wistar machos foram divididos em cinco grupos (n=8-10/grupo): grupo sham (SHAM), grupo infarto (IM), grupo infarto+HT (IM+HT), grupo infarto+carvedilol (IM+C) e grupo infarto+C+HT (IM+C+HT). Após o IAM, os grupos SHAM e IM receberam salina, e os tratados receberam seus respectivos tratamentos por 12 dias por gavage. Após esse período, os animais foram submetidos a uma avaliação ecocardiográfica, e, posteriormente, ao cateterismo venticular. Em seguida, os animais foram eutanasiados para a coleta do coração, do pulmão e do fígado, para análises morfométricas e bioquímicas. Análise estatística: ANOVA de uma via seguida pelo teste de Student-Newman-Keuls. Nível de significância P<0,05. Resultados: A respeito dos parâmetros morfométricos, foi possível verificar hipertrofia cardíaca nos grupos infartados tratados em relação aos grupos SHAM e IM. Quanto aos parâmetros ecocardiográficos, os grupos tratados demonstraram aumento da espessura da parede posterior na sístole, da fração de ejeção e redução do índice de tensão de parede em comparação ao grupo IM. Os grupos IM+C e IM+C+HT também apresentaram atenuação da redução da mudança de área fracional e do aumento do volume sistólico final em relação aos grupos IM e IM+HT. Quanto aos parâmetros hemodinâmicos, houve redução das dP/dt máxima e mínima, da pressão sistólica do ventrículo esquerdo (VE) e aumento da pressão diastólica final do VE no grupo IM em comparação ao SHAM. Entretanto, todos esses parâmetros foram revertidos nos grupos tratados. A frequência cardíaca aumentou nos grupos IM+HT e IM+C+HT em relação aos outros grupos, mas reduziu no grupo IM+C+HT em relação ao grupo IM+HT. Quanto aos parâmetros de estresse oxidativo, verificou-se aumento dos níveis de espécies reativas de oxigênio (ERO) e redução dos níveis de sulfidrilas no grupo IM e IM+C em relação ao grupo SHAM, enquanto os grupos IM+HT e IM+C+HT não foram diferentes do grupo SHAM. Ainda, no grupo IM+C+HT, o co-tratamento apresentou efeito sinérgico na redução dos níveis de ERO e no aumento da razão GSH/GSSG. Conclusão: A coadminsitração do carvedilol e dos HT foi capaz de melhorar o remodelamento ventricular e a função cardíaca após o IAM. Ainda, o carvedilol foi capaz de exercer seu efeito betabloqueador no grupo IM+C+HT, uma vez que reduziu a frequência cardíaca aumentada pelos HT. Além disso, a co-administração apresentou um efeito sinérgico positivo nos parâmetros de estresse oxidativo, especificamente, sobre os níveis de ERO e o balanço redox através da razão GSH/GSSG, dessa forma preservando a homeostase redox do tecido cardíaco. / Introduction: After acute myocardial infarction (AMI), treatment with thyroid hormones (TH) has revealed cardioprotective effects. However, TH causes adrenergic stimulation, which effect increase heart rate and this may contribute to ventricular dysfunction progression after AMI. Meanwhile, the beta-blocker carvedilol is able to block adrenergic stimulation. Aim: To evaluate the effects of TH and carvedilol co-administration on the heart of rats submitted to AMI. In this context, it focused on the effects of this co-administration on ventricular remodeling, cardiac function and oxidative stress. Material and methods: Male Wistar rats were divided in five groups (n=8-10/group): sham (SHAM), infarcted (MI), infarcted+TH (MI+TH), infarcted+carvedilol (MI+C) and infarcted group+C+TH (IM+C+TH). Post-AMI, SHAM and MI groups received saline, and the treated groups received their respective treatments for 12 days by gavage. After this period, the animals were submitted to an echocardiographic evaluation and, later, to the ventricular catheterization. Afterwards, the animals were euthanized for the heart lung and liver collection, for morphometric and biochemical analyzes. Statistical Analysis: One-way ANOVA followed by Student-Newman-Keuls test. Significance level P<0,05. Results: Regarding the morphometric parameters, it was possible to verify cardiac hypertrophy in the treated infarcted groups in relation to the SHAM and MI groups, as well as there was no significant difference between the groups regarding pulmonary and hepatic congestion. In relation to echocardiographic parameters, treated groups showed an increase in systolic posterior wall thickness, ejection fraction and a reduction in wall tension index compared to MI group. MI+C and MI+C+TH groups also presented attenuation of the reduction in the fractional area change and of the increase in the final systolic volume in relation to the MI and MI+TH groups. Regarding the hemodynamic parameters, there was a reduction of the maximum and minimum dP/dt, the left ventricular (LV) systolic pressure and an increase in the final LV diastolic pressure in the MI group compared to SHAM. However, all these parameters were reversed in the treated groups. The heart rate increased in the MI+TH and MI+C+TH groups compared to the other groups, but decreased in the MI+C+TH group compared to the MI+TH group. Regarding the parameters of oxidative stress, there was an increase in the levels of reactive oxygen species (ROS) and reduction of sulfhydryl levels in the MI and MI+C groups compared to the SHAM group, while the MI+TH and MI+C groups were not different from the SHAM group. In addition, in the M+C+TH group, the co-treatment showed a synergic effect in reducing ERO levels and increasing GSH/GSSG ratio. Conclusion: Coadministration of carvedilol and TH was able to improve ventricular remodeling and cardiac function after AMI. In addition, carvedilol was able to exert its betablocking effect in the MI+C+TH group, since it reduced the heart rate increased by TH. In addition, co-administration had a positive synergistic effect on oxidative stress parameters, specifically on ROS levels and redox balance through the GSH/GSSG ratio, thus preserving redox homeostasis of cardiac tissue.

Hormônios tireóideos

Antagonistas adrenérgicos beta

Infarto agudo do miocárdio

Estresse oxidativo

Carvedilol

Oxidative stress

Ventricular remodeling

Acute myocardial infarction

Thyroid hormones

Sistema complemento e resposta de produção de anticorpos em ratos hipertireoideos / Complement System and response of production of antibody in rats with hyperthyroidism

Bitencourt, Claudia da Silva

15 February 2007

Tendo em vista a ocorrência de alterações no sistema imune relacionadas ao hipertireoidismo e à participação do sistema complemento (SC) em processos imunológicos, torna-se importante investigar se os hormônios tireoidianos teriam algum efeito sobre o SC. O SC é composto de uma série de proteínas séricas e de membrana que estão envolvidas em processos da resposta imune. Considerando que os hormônios tireoidianos estão envolvidos em uma série de processos biológicos, e que tanto o hipo- quanto hipertireoidismo podem acarretar alterações importantes nestes processos, os objetivos deste trabalho foram estudar o impacto de níveis séricos elevados de hormônios tireoidianos sobre a atividade do sistema complemento e produção de anticorpos. Foram utilizados ratos machos wistar para o modelo experimental de hipertireoidismo, investigando-se a atividade lítica das vias clássica/lectina e alternativa através de ensaios hemolíticos; os níveis séricos de fator B da via alternativa através do emprego de reagente deficiente de fator B; e a produção de anticorpos anti-hemácia de carneiro (SRBC) empregando ELISA (enzyme linked immunosorbent assay) e ensaios de plaque forming cell (PFC). O hipertireoidismo induzido não resultou em alterações da atividade lítica das vias clássica/lectina. Entretanto, a elevação dos níveis séricos de hormônios tireoidianos provocou uma redução da atividade lítica de via alternativa, de forma significante em doses de 1, 5, 50 e 100g de levotiroxina/200g de peso animal após 14 dias de tratamento, e com dose a partir de 0,15g de triiodotironina/200g de peso animal, após 7 e 12 dias de tratamento. Os níveis séricos funcionais de fator B foram reduzidos nestas condições. Além disso, ocorre redução da resposta de produção de anticorpos em ratos tratados com T3 e imunizados com SRBC. Estes resultados mostram que níveis elevados de hormônio tireoideano reduzem a capacidade funcional da via alternativa do SC , avaliada pelo desencadeamento da lise em decorrência da interação com hemácias de coelho. Esta redução poderia levar a uma menor geração de fragmentos com atividade nos processos de seqüestro e apresentação do antígeno e interação com as células envolvidas na resposta imune, resultando em títulos menores de anticorpos produzidos. Estudos adicionais são necessários para avaliar estas possibilidades. As observações deste estudo podem auxiliar para o melhor entendimento do impacto biológico das disfunções hormonais sobre a atividade do sistema complemento. / Considering the alterations of the immune system that occur in the hyperthyroidism, and the involvement of the complement system (CS) in immune processes, this work aimed to investigate the effect of high levels of thyroid hormones on the CS and on the antibody production. The CS comprehends a group of serum and membrane proteins which activation leads to the generation of protein fragments or complexes with important biologic functions, such as participation in events of the immune response. Wistar adult male rats treated with thyroid hormones were used as experimental model of hyperthyroidism, to evaluate the lytic activity of classical/lectin and alternative pathways of the CS through hemolytic assays; the serum levels of factor B employing serum deficient of this component (RB); and the production of anti-sheep red blood cells (SRBC) antibodies through enzyme linked immunosorbent (ELISA) and plaque forming cell (PFC) assays. Classic and lectin pathways activity was not affected in the hyperthyroidism. However in this condition the alternative pathway activity was significantly reduced at doses of 1; 5; 50 and 100 g of thyroxine (T4) /200g of animal weight/day after 14 days of treatment, or crescent doses starting from 0,15 g of triiodothyronine (T3) for periods of 7 and 12 days of treatment. The serum levels of factor B were also reduced in these conditions. In addition, there was a reduction of the antibody response in rats treated with T3 and immunized with SRBC. These results show that the functional capacity of alternative pathway is decreased in consequence of high levels of thyroid hormones as evaluated by its lytic potency triggered by the rabbit erythrocytes. This could them lead to a reduced generation of complement fragments active in antigen sequestering and presentation, and on the interaction of cells in the immune response decreasing the antibody production. Additional studies are required to evaluate these possibilities.

alternative pathway

and immune response

antibody production

complement system

hormônios tireoidianos

produção de anticorpos

resposta imune

sistema complemento

thyroid hormones

via alternativa

Avaliação da função e do volume da tireoide em crianças saudáveis

Campos, Tatiane de

January 2011

Durante a vida fetal e a infância, os processos fisiológicos da tireoide são peculiares, sendo os hormônios tireoidianos (T3 e T4) essenciais para o crescimento e o desenvolvimento da criança. Os níveis séricos de tireotrofina (TSH) são determinantes no diagnóstico de disfunção tireoidiana. Os dados de normalidade e os fatores que influenciam os níveis de TSH em crianças são pouco conhecidos, sendo que os estudos que disponibilizam esses dados nem sempre são bem conduzidos. A síntese de hormônios tireoidianos é dependente de iodo, e a deficiência desse elemento associa-se a alterações morfológicas e volumétricas da glândula. Os valores de normalidade para volume tireoidiano na infância são influenciados pelas medidas antropométricas e variam entre populações. Atualmente, a deficiência grave de iodo tem dado lugar a patologias relacionadas à ingestão excessiva desse elemento. É importante conhecer as particularidades e os valores de referência para função tireoidiana na infância a fim de evitar prejuízos antropométricos e cognitivos. / Distinct physiological processes occur in the thyroid gland during intrauterine life and childhood, with thyroid hormones (T3 and T4) playing an essential role in growth and development. Serum levels of thyroid-stimulating hormone (TSH) are determining factors of the diagnosis of thyroid dysfunction. Little is known about the normal range of TSH in children and the factors that influence TSH levels in this population, and the few studies that have addressed this issue have not all been well designed and conducted. Thyroid hormone synthesis is iodine-dependent, and iodine deficiency is associated with pathological changes in the morphology and volume of the thyroid gland. The normal range of thyroid volume in children is influenced by anthropomorphic parameters, and varies among populations. Severe iodine deficiency has now been surpassed by conditions associated with excessive iodine intake. Knowledge of the peculiarities of thyroid function in childhood and of the reference ranges of thyroid function tests in this period is important for the prevention of anthropometric and cognitive impairments.

Hormônios tireóideos

Criança

Glândula tireóide

Testes de função tireóidea

Iodo

Thyroid hormones

TSH

Children

Thyroid volume

Iodine

Reference ranges

Efeito do hormônio tireoideano sobre a expressão gênica do transportador de creatina (SLC6A8: CreaT) na musculatura esquelética e cardíaca de ratos. / Effect of thyroid hormone upon creatine transporter (CreaT: SLC6A8) gene expression in skeletal and cardiac muscles in rats.

Ferreira, Lucas Guimarães

05 December 2008

A creatina (Cr) é uma reserva de fosfato de alta energia, sendo a fonte mais rápida de restauração do ATP intracelular. O hormônios tireoideano participa de forma importante na manutenção da taxa metabólica, aumentando a síntese e consumo de ATP, por meio da regulação de diferentes genes-alvo. Neste sentido, avaliamos o efeitos do HT sobre a expressão gênica do transportador de Cr nos músculos esqueléticos e cardíaco de ratos. O tratamento com o hormônio regula estes processos, porém de forma distinta nos diferentes tipos de músculos. / Creatine (Cr) is a high-energy phosphate reservoir and the fastest source for intracellular ATP regeneration. The thyroid hormone plays a key role on the maintenance of basal metabolic rate, increasing the synthesis and the degradation of ATP through regulation of target-genes. In this study, we explore the effects of thyroid hormone on Cr transporter gene expression and regulation of intracellular pool of Cr in skeletal and cardiac muscles in rats. The hormone can regulate these processes in distinct ways in different muscle types.

Cardiac muscle

Creatina

Creatine

Creatine transporter

Hormônios tireoideanos

Músculo cardíaco

Músculo esquelético

Skeletal muscle

Thyroid hormones

Transportador de creatina