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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Untersuchungen zur Rolle des Monocarboxylattransporters 8 anhand des Knock-out Mausmodells

Wirth, Eva Katrin 13 April 2011 (has links)
Schilddrüsenhormone benötigen als geladene Proteine Transporter um Zellmembranen zu durchqueren. Ein sehr spezifisches Transportprotein ist der Monocarboxylattransporter 8 (Mct8). Mutationen in MCT8 führen beim Menschen zu einer schweren X-gekoppelten mentalen Retardierung, die mit sehr speziellen Veränderungen der Schilddrüsenhormonwerte im Serum einher geht. Zur genaueren Untersuchung der Funktion von Mct8 sowie Mechanismen der Erkrankung wurde ein Knock-out Mausmodell für Mct8 generiert und mit dem menschlichen Phänotyp verglichen. Mct8-defiziente Mäuse replizieren den humanen Phänotyp in Hinsicht auf veränderte Schilddrüsenhormonparameter im Serum. Dennoch weisen diese Mäuse keine morphologischen Veränderungen des Gehirns auf. Ein in dieser Arbeit erstmalig nachgewiesenes ähnlich einer Hyperthyreose verändertes Angstverhalten sowie ein ähnlich einer Hypothyreose verändertes Putzverhalten führte zu der Hypothese, dass es andere Transporter gibt, die den Verlust von Mct8 kompensieren. Ein Kandidat mit einem ähnlichen Expressionsmuster in verschiedenen Geweben und auch in Zelltypen des Gehirns ist der L-Typ Aminosäuretransporter 2 (Lat2). Mct8 ist bei der Maus und beim Menschen während der Entwicklung stark in Neuronen und anderen Zelltypen des Gehirns exprimiert. LAT2 ist jedoch anders als bei der Maus beim Menschen während der Entwicklung in Neuronen nicht nachweisbar. Lat2 könnte also bei der Maus, jedoch nicht beim Menschen den Verlust von Mct8 während der Gehirnentwicklung kompensieren und somit den Unterschied zwischen beiden Phänotypen erklären. Die Untersuchung von Mct8-defizienten Mäusen konnte jedoch auch einen neuen Phänotyp aufdecken: das Fehlen von Mct8 führt bei Mäusen mit zunehmendem Alter zu Hyperplasien der Schilddrüse, die als papilläre Schilddrüsenkarzinome klassifiziert wurden. Bei einem Patienten mit Allan-Herndon-Dudley-Syndrom konnten hierauf ebenfalls hyperplastische Veränderungen der Schilddrüse gefunden werden. / Thyroid hormones are charged molecules and therefore need transporters to cross the cell membrane. One very specific transport protein is the monocarboxylatetransporter 8 (Mct8). Mutations in MCT8 lead to a severe form of X-linked mental retardation in humans in combination with very specific changes in thyroid hormone serum parameters. A mouse model of Mct8-deficiency was generated and compared to the human phenotype to be able to precisely analyze functions of Mct8 and mechanisms of the disease. Mct8-deficient mice do replicate the human phenotype concerning changes of thyroid hormones in serum. However, these mice did not show any morphological changes in the brain. This work could show for the first time changes in anxiety-related behaviour indicative of hyperthyroidism as well as changes in grooming behaviour indicative of hypothyroidism. This led to the hypothesis that other transporters exist that can compensate for the loss of Mct8. One candidate that has a similar expression pattern in different tissues and cell types of the brain is the L-type amino acid transporter 2 (Lat2). Mct8 is highly expressed in neurons and other cell types of mice and humans during development. LAT2 is in contrast to the mouse not detectable in human developing neurons. Therefore, Lat2 could compensate in the mouse but not in the human for the loss of Mct8 during brain development. This could explain the differences between both phenotypes. Nevertheless, the analysis of Mct8-deficient mice could also disclose a new phenotype: the loss of Mct8 leads to thyroid hyperplasia in mice that increases with age and could be classified as papillary thyroid carcinoma. Thereupon, hyperplastic changes of the thyroid could also be detected in a patient with Allan-Herndon-Dudley syndrome.
2

Deiodination of Thyroid Hormones by Iodothyronine Deiodinase Mimics

Manna, Debasish January 2013 (has links) (PDF)
Thyroxine is the main secretory hormone of thyroid gland and it is produced in thyroglobulin by thyroid peroxidase/hydrogen peroxide/iodide system. After biosynthesis and secretion of thyroxine, it undergoes multiple metabolic reactions. The most important metabolic pathway is the stepwise deiodination from the inner ring or outer ring. Removal of one of the outer ring or phenolic ring iodines of biologically less active T4, leads to the formation of 3,5,3'-triiodothyronine or T3, a compound which is biologically more active. On the other hand, removal of one of the inner ring or tyrosyl ring iodines gives 3,3',5'-triiodothyronine (3,3',5'-T3 or rT3) which is a biologically inactive thyroid hormone. Three enzymes involved in this activation and inactivation pathway of thyroid hormones are known as iodothyronine deiodinases (IDs), which are dimeric integral-membrane selenoproteins. Depending upon the sequence and substrate specificity, three iodothyronine deiodinase enzymes have been identified, iodothyronine deiodinase-1 (ID-1), iodothyronine deiodinase-2 (ID-2) and iodothyronine deiodinase-3 (ID-3). ID-1 can catalyze both inner ring and outer ring deiodination of thyroid hormones whereas, ID-2 is selective to the outer ring deiodination. The type-1 and -2 deiodinases (ID-1 and ID-2) produces the biologically active hormone 3,5,3′-triiodothyronine (T3). These two enzymes also convert 3,3′,5′-triiodothyronine (reverse T3 or rT3) to 3,3′-diiodothyronine (3,3′-T2) by outer-ring deiodination (Scheme 1). The type-3 deiodinase (ID-3) catalyzes the convertion of T4 to rT3 by an inner-ring deiodination pathway. Apart from deiodination, there are several alternate pathways of thyroid hormone metabolism, which include sulfate conjugation and glucoronidation of the phenolic hydroxyl group of iodothyronines, the oxidative deamination and decarboxylation of the alanine side chain to form thyroacetic acid and thyronamines, respectively. Glucoronidation and sulfate conjugation changes the physico-chemical properties of iodothyronines dramatically. This thesis consists of five chapters. The first chapter provides a general introduction of biosynthesis of thyroid hormones and followed by deiodination by three iodothyronine deiodinase enzyme. This chapter also provides an overview of thyroid hormone transport and different transport proteins and their mode of binding with thyroid hormones. Apart from this, this chapter also provides a brief overview on other thyroid hormone metabolites. In the second chapter of the thesis, initial attempts in the development of different iodothyronine deiodinase mimics have been discussed. Goto et al have shown that the sterically hindered selenol 1 converts the thyroxine derivative 3 (N¬butyrylthyroxine methyl ester) to the corresponding triiodo derivative 4 by an outer-ring deiodination (Scheme 2). Although the reaction was carried out in organic solvent and a relatively higher temperature (50 °C) and longer reaction time (7 days) were required for about 65% deiodination, this study also provides an experimental evidence for the formation of selenenyl iodide (2) in the deiodination of a thyroxine derivative by an organoselenol. However, only one iodine was removed from the outer ring of 3, no inner ring deiodination was detected (Scheme 2). Interestingly, when compound 5 was treated with selenol 1 under similar conditions, no deiodination was observed (Scheme 3). This leads to assumption that presence of free phenolic hydroxyl group is important for the deiodinase activity. Based on this experimental observation, they proposed a mechanism which involves an enol¬keto tautomerism of the phenolic hydroxyl group. In the case of thyroxine, the outer-ring can undergo enol-keto tautomerism, whereas due to lack of free hydroxyl group, the inner ring cannot undergo similar kind of tautomerism. The enol-keto tautomerism probably makes the outer ring iodines more reactive than the inner ring iodines of thyroxine. We have developed tthe first chemmical modell for the inneer ring deioddination of TT4 and T3 by type 33 deiodinase . We have shown that naphthyl-baseed selenol 6 bearing a thhiol group in the cloose proximitty to the sellenium act aas an excelleent model foor ID-3 by selectively deiodinatting T4 andd T3 to prodduce rT3 annd 3,3'-T2, rrespectively,, under physiological relevant conditions. When 2 equuivalent of ccompound 66 was emplooyed in the assay, an almost quuantitative cconversion oof T4 to rT3 was observeed within 300 hours and there was no indicaation of the fformation off T3 or 3,3'-TT2. When the selenol group was repplaced with a thiol group in compouund 7, the ddeiodinase activity wwas decreassed. On thee other handd, when thee thiol groupp was replaaced with selenol mmoiety in commpound 8, thhe deiodinasse activity drramatically iincreased wiithout any change iin the selecttivity. Comppounds 10 and 11 havving N-methhylamino grooup were found too be more aactive than the correspponding unssubstituted ccompounds 7 and 8, respectively. However, introduction of a secondary amine adjacent to the selenol moiety into the compound 9 significantly reduces the deiodinase activity. In the third chapter synthesis, deiodinase activity and mechanism of deiodination of a series of peri-substituted naphthalene derivatives is discussed. Iodobenzene was used as halogen bond donor for the DFT calculations. From the orbital analysis it is observed that there is perfect orbital symmetry match between the HOMO of compound 8 (selenolate form) and LUMO of iodobenzene. When the selenolate form of 1-selenonaphthol interacts with iodobenzene, a halogen bonded adduct is formed. The negative charge on the selenium center decreases as it donates electron pair to the σ* orbital of C–I bond in iodobenzene and as a consequence the positive charge on the iodine center decreases (Figure 1). Addition of iodobenzene to 1-selenonaphthol led to a significant downfield shift in 77Se NMR spectrum of 1-selenonaphthol and with an increase in the concentration of iodobenzene, more downfield shift in the signal was observed. Figure 1. The charges obtained from Natural Bond Orbital (NBO) analysis for the selenolate form of (a) 1-selenonaphthol (b) iodobenzene, (c) halogen-bonded adduct On the basis of experimental end theoretical data, a mechanism for the deiodination of T4 by compound 8 is proposed. According to the mechanism, the initial interaction of one of the selenol moieties with an iodine leads to the formation of halogen bond. The transfer of electron density from selenium to the σ* orbital of the C−I bond generates a σ-hole or partial positive charge on the selenium atom, which facilitates an interaction between the halogen bonded selenium atom and the free selenol (selenolate) moiety (intermediate 12). The selenium−selenium interaction (chalcogen bond) strengthens the halogen bond, leading to a heterolytic cleavage of the C−I bond. The protonation of the resulting carbanion leads to the formation of rT3. On the other hand, the formation of an Se−Se bond produces the diselenide 13 with elimination of iodide as HI. The reductive cleavage of the Se−Se bond in compound 13 regenerates the diselenol 8 (Figure 2). In the fourth chapter deiodination of sulfated thyroid hormones is discussed. Sulfate conjugation is an important step in in the irreversible inactivation of thyroid hormones. Sulfate conjugation of the phenolic hydroxyl group stimulates the inner ring deiodination of T4 and T3 but it blocks the outer ring deiodination of T4 by ID-1. The thyroxine sulfate (T4S) undergoes faster deiodination as compared to the parent thyroid hormone T4. Only ID-1 catalyzes the deiodination of sulfated thyroid hormones. In contrast, ID-2 and ID-3 do not accept T4S and/or T3S as substrate. We have shown that iodothyronine sulfates can be readily deiodinated by synthetic deiodinase model compound 8 and its derivatives. In contrast to the inner ring-selective deiodination of T4, the synthetic compounds loses the selectivity and mediate both inner and outer-ring deiodination of T4S and outer ring deiodination of rT3S. From this study, we have also proposed that the enol-keto tautomerism is probably not required for the outer ring deiodination and the strength of halogen bonding controls the regioselective deiodination by model compounds. In the fifth chapter, the mechanism of inhibition of iodothyronine deiodinases by PTU and IAA is discussed with the help of model compounds. In the model study, it has been observed that compound 8 does not form a stable Se-I intermediate (14), which is essential for the formation of Se-S covalent bond with PTU. As a consequence, the deiodination of T4 by compound 8 is not inhibited by PTU. This study supports the proposal that ID-3 does not follow a ping-pong bi-substrate pathway for deiodination and may not form a stable E-Se-I intermediate, which is responsible for the insensitivity of ID-3 towards PTU. The biphenyl based diselenol 15 reacts with IAA and iodoacetamide to form the corresponding carboxymethylated product 17. On the other hand, compound 8 does not undergo the expected carboxymethylation by IAA and iodoacetamide, but they readily deiodinate both IAA and iodoacetamide. Based on this model study, a possible model is proposed for the insensitivity of ID-3 towards IAA. Iopanoic acid (18) is a well known radiocontrast agent and is used as adjunctive therapy with PTU and CBZ for the treatment of thyrotoxicosis.[9] We show in this chapter that iopanoic acid undergoes monodeiodination by compound 8 under physiological relevant conditions. The deiodinated products (19 and 20) from iopanoic acid are characterized by NMR spectroscopy and single crystal X-ray crystallography. It is observed that after monodeiodination, the strength of halogen bonding decreases and therefore, the monodeiodinated products do not undergo further deiodination.

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