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A study of the role of phospholipid hydroperoxide glutathione peroxidase activity in humansHurst, Rachel January 1999 (has links)
No description available.
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Hepatic injury in metabolic syndrome : the role of selenium in models of hepatic injury and healingBaghdadi, Hussam Hussein January 2009 (has links)
Oxidative stress, lipid peroxidation, and endotoxaemia with cytokine-mediated injury have been implicated as factors in the pathogenesis of non-alcoholic fatty liver disease (NAFLD). The degree of insulin resistance together with co-existing inadequacies of vital antioxidant defence mechanisms may be important determinants of progression to fibrosis in patients with non-alcoholic steatohepatitis (NASH). Current therapies are targeted at improving insulin sensitivity as well as addressing hepatic repair including anti-inflammatory strategies. Anti-oxidants remedies have also been tested but the role of selenoenzymes with antioxidant action, namely thioredoxin reductase 1 (TR1) and glutathione peroxidase 1 (GPX1) have been ignored. The aim of this thesis is to investigate the role of selenium in the pathophysiology of NAFLD both in vitro and in vivo. The in vitro studies used cell lines representing the cell types involved in the disorder; hepatocytes (C3A line) and hepatic stellate cells (LX-2 line). In order to assess the influence of selenium status and selenoenzymes expression on the pathogenesis of NAFLD it was necessary to develop a culture system which allowed good cell viability in selenium free culture medium. This was achieved by the use of an insulin and transferrin (IT)-supplemented medium which importantly was free of any animal serum additions. Using this IT culture medium, selenium addition (as selenite) produced a significant increase in the expression of GPX1 and TR1 in both C3A and LX2 cells. TR1 and GPX1 were expressed at similar levels in both C3A and LX-2 cells. It was also necessary to develop an in-vitro model for fat loading C3A cells to mimic fatty liver pathophysiology. Two models of fat loading were investigated. One model used lactate, pyruvate, octanoate and ammonium (LPON). LPON has been previously used to increase the functionality of C3A cells but it was observed that fat droplets accumulated in these LPON treated cells. Dissection of the agents in the LPON revealed that octanoate was the factor that increased the triglyceride accumulation. Interestingly, octanoate also increased the expression of TR1 and GPX1, suggesting that it could induce oxidative stress leading to the induction of selenoenzymes to afford a protective defence mechanism. In the second model, oleate and/or palmitate were used to fat-load C3A cells. These cells had significantly higher triglyceride content than the LPON-fat-loaded cells. However, oleate and/or palmitate treatments did not increase the expression of either TR1 or GPX1 in C3A cells suggesting perhaps these cells were not under oxidative stress. LPON and oleate/palmitate were also capable of fat loading LX2 cells. Selenium-supplementation of C3A and LX-2 cells efficiently protected (measured by their lactate dehydrogenase retention) them from oxidative damage induced by t-butylhydroperoxide. This suggests that selenium supplementation through its incorporation into selenoenzymes could protect the cells from the oxidative damage. The role of selenium was also investigated in the regulation of α-1 pro-collagen mRNA expression. In LX-2 cells, the expression of α-1 pro-collagen mRNA was unaffected by the selenium status of the cell. Similarly the selenium status of C3A cells had no effect on modifying α-1 pro-collagen mRNA of LX2 cells when co-culture or conditioned medium experiments were performed. These results suggest that LX-2 cells were already largely activated and at a stage unable to be ameliorated by selenium treatment. In contrast, studies on C3A cells revealed that TGF-β1 (common inducer of α-1 pro-collagen mRNA in hepatic stellate cells) dramatically increased the expression of α-1 pro-collagen mRNA in C3A cells to the levels observed in LX-2 cells. More interestingly, selenium supplementation of C3A cells notably decreased α-1 pro-collagen mRNA expression in response to TGF-1. In the in vivo study, plasma selenium in type 2 diabetics (high risk of developing NAFLD) were inversely related to the body mass index and in most patients selenium levels were below that required to maximally express GPX1 in red cells. Furthermore, type 2 diabetics had lower plasma selenium levels compared to the healthy control group. Collectively, this suggests that in the UK population, obesity is a risk factor for both insulin resistance and decreased selenium status leading to sub-optimal antioxidant protection. In conclusion, this study provides evidence that selenium through increasing the expression of selenoenzymes is beneficial in protecting liver cells from oxidative stress. Furthermore, selenium is capable of suppressing α-1 pro-collagen mRNA expression in hepatocytes although not in activated hepatic stellate cells. Taken together these data support the view that suboptimal selenium intake in the UK may be a risk factor in the pathogenesis of NAFLD.
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Selen in der IntensivmedizinZimmermann, Thomas, Albrecht, Steffen, Hanke, S., von Gagern, Georg 19 February 2014 (has links) (PDF)
Mit der Entdeckung des Selens als essentielles Spurenelement und der Glutathionperoxidase als Selenoenzym sowie der Tatsache, daû Selenmangel relativ weit verbreitet ist, wurde erstmals ein Zusammenhang zu einigen schweren Erkrankungen hergestellt (Keshan-Krankheit, Kaschin-Beck-Syndrom). Interessant ist dabei, daû sich trotz dieser und anderer bekannter Selenmangelerkrankungen eine Therapie in der Humanmedizin nur langsam zu etablieren beginnt, waÈ hrend die Selensupplementation in der VeterinaÈ rmedizin bereits Standard ist. Die Autoren beschaÈ ftigen sich seit 1990 mit der Rolle des Spurenelements Selen bei septischen Krankheitsbildern in der Intensivmedizin, beim ReperfusionsphaÈnomen nach gefaÈûchirurgischen Eingriffen und in der Onkologie. Sie konnten zeigen, daû die adjuvante Therapie der akuten Pankreatitis und der Sepsis mit Natriumselenit einen positiven Effekt auf das Outcome der Patienten zu haben scheint (eine multizentrische, doppelblinde, randomisierte Sepsisstudie zur Validierung dieser Ergebnisse ist in Vorbereitung). Neue Erkenntnisse zur Beeinflussung von Transkriptionsfaktoren durch Selen bei systemischem Inflammationssyndrom und Sepsis erlauben eine wissenschaftlich fundierte Interpretation der klinischen Ergebnisse. Weitere molekularbiologische Untersuchungen werden das Spurenelement Selen zu einem der interessantesten Forschungsprojekte der naÈ chsten 10 Jahre in Intensivmedizin und Onkologie machen. / Since selenium was discovered as an essential trace element being widely distributed, and since glutathione peroxidase is known as a selenoenzyme, associations with several severe diseases were established (Keshan disease, Kaschin-Beck syndrome). Despite these known selenium deficiency diseases a related human therapy is still not established so far. In veterinary medicine, however, substitution of selenium is already a standard therapy. Our laboratory investigates the role of selenium since 1990. This includes investigations about the effects of selenium in acute inflammatory diseases in intensive care, in the reperfusion phenomenon following vascular surgery, and in oncology. In acute pancreatitis and sepsis, adjuvant therapy using sodium selenite seems to have positive effects on the overall outcome of patients (a multicenter, double-blind, randomized trial on sepsis is being prepared). New findings concerning the influence of selenium on transcription factors in inflammatory processes will permit a scientifically sound interpretation of clinical results. With further investigations in molecular biology the trace element selenium will become, in the next decade, one of the most interesting topics in intensive care and oncology. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Účinky vybraných přírodních látek na antioxidační systém organismu / Effects of selected natural substances on the antioxidant system of an organismHodková, Anna January 2016 (has links)
of study named: Effects of selected natural substances on the antioxidant system of an organism Developed: Mgr. Anna Hodková Department of Pharmacology and Toxikology, Faculty of Medicine in Pilsen, Charles University in Prague Pilsen 2016 The aim of this study was to compare the effects of selected natural substances on the antioxidant defense system under comparable conditions, focusing on influencing the activity of selenoenzymes thioredoxin reductase (TrxR-1) and glutathione peroxidase (GPx-1). Experiments were performed in rats (Wistar, male). Livers, and in some cases kidneys were collected in all experiments. Homogenates were created from the collected organs and subsequently the activity of TrxR-1 and GPx-1, glutathione reductase (GR), catalase (CAT) and superoxide dismutase (SOD), and reduced glutathione (GSH) and lipid peroxidation (LP) levels were determined. We demonstrated significant effects of selected natural substances on the redox system, including influences of selenoenzymes thioredoxin reductase and glutathione peroxidase. The biggest influence on the activity of selenoenzymes thioredoxin reductase and glutathione peroxidase had hydroxytyrosol (HT) and oleuropein (OLEU). In rat liver tissue there was a significant decrease of the activity of both above mentioned enzymes after...
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Selen in der IntensivmedizinZimmermann, Thomas, Albrecht, Steffen, Hanke, S., von Gagern, Georg January 2000 (has links)
Mit der Entdeckung des Selens als essentielles Spurenelement und der Glutathionperoxidase als Selenoenzym sowie der Tatsache, daû Selenmangel relativ weit verbreitet ist, wurde erstmals ein Zusammenhang zu einigen schweren Erkrankungen hergestellt (Keshan-Krankheit, Kaschin-Beck-Syndrom). Interessant ist dabei, daû sich trotz dieser und anderer bekannter Selenmangelerkrankungen eine Therapie in der Humanmedizin nur langsam zu etablieren beginnt, waÈ hrend die Selensupplementation in der VeterinaÈ rmedizin bereits Standard ist. Die Autoren beschaÈ ftigen sich seit 1990 mit der Rolle des Spurenelements Selen bei septischen Krankheitsbildern in der Intensivmedizin, beim ReperfusionsphaÈnomen nach gefaÈûchirurgischen Eingriffen und in der Onkologie. Sie konnten zeigen, daû die adjuvante Therapie der akuten Pankreatitis und der Sepsis mit Natriumselenit einen positiven Effekt auf das Outcome der Patienten zu haben scheint (eine multizentrische, doppelblinde, randomisierte Sepsisstudie zur Validierung dieser Ergebnisse ist in Vorbereitung). Neue Erkenntnisse zur Beeinflussung von Transkriptionsfaktoren durch Selen bei systemischem Inflammationssyndrom und Sepsis erlauben eine wissenschaftlich fundierte Interpretation der klinischen Ergebnisse. Weitere molekularbiologische Untersuchungen werden das Spurenelement Selen zu einem der interessantesten Forschungsprojekte der naÈ chsten 10 Jahre in Intensivmedizin und Onkologie machen. / Since selenium was discovered as an essential trace element being widely distributed, and since glutathione peroxidase is known as a selenoenzyme, associations with several severe diseases were established (Keshan disease, Kaschin-Beck syndrome). Despite these known selenium deficiency diseases a related human therapy is still not established so far. In veterinary medicine, however, substitution of selenium is already a standard therapy. Our laboratory investigates the role of selenium since 1990. This includes investigations about the effects of selenium in acute inflammatory diseases in intensive care, in the reperfusion phenomenon following vascular surgery, and in oncology. In acute pancreatitis and sepsis, adjuvant therapy using sodium selenite seems to have positive effects on the overall outcome of patients (a multicenter, double-blind, randomized trial on sepsis is being prepared). New findings concerning the influence of selenium on transcription factors in inflammatory processes will permit a scientifically sound interpretation of clinical results. With further investigations in molecular biology the trace element selenium will become, in the next decade, one of the most interesting topics in intensive care and oncology. / Dieser Beitrag ist mit Zustimmung des Rechteinhabers aufgrund einer (DFG-geförderten) Allianz- bzw. Nationallizenz frei zugänglich.
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Účinky vybraných přírodních látek na antioxidační systém organismu / Effects of selected natural substances on the antioxidant system of an organismHodková, Anna January 2016 (has links)
of study named: Effects of selected natural substances on the antioxidant system of an organism Developed: Mgr. Anna Hodková Department of Pharmacology and Toxikology, Faculty of Medicine in Pilsen, Charles University in Prague Pilsen 2016 The aim of this study was to compare the effects of selected natural substances on the antioxidant defense system under comparable conditions, focusing on influencing the activity of selenoenzymes thioredoxin reductase (TrxR-1) and glutathione peroxidase (GPx-1). Experiments were performed in rats (Wistar, male). Livers, and in some cases kidneys were collected in all experiments. Homogenates were created from the collected organs and subsequently the activity of TrxR-1 and GPx-1, glutathione reductase (GR), catalase (CAT) and superoxide dismutase (SOD), and reduced glutathione (GSH) and lipid peroxidation (LP) levels were determined. We demonstrated significant effects of selected natural substances on the redox system, including influences of selenoenzymes thioredoxin reductase and glutathione peroxidase. The biggest influence on the activity of selenoenzymes thioredoxin reductase and glutathione peroxidase had hydroxytyrosol (HT) and oleuropein (OLEU). In rat liver tissue there was a significant decrease of the activity of both above mentioned enzymes after...
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The Effect of Substituents and Solvents on the Deiodination Reactions of Thyroid Hormones by Iodothyronine Deiodinase MimicsRaja, K January 2016 (has links) (PDF)
Thyroid hormones (THs; T4 and T3), secreted from thyroid gland, play an important role in human growth and development. T3 (3,5,3′-triiodothyronine) is the active hormone and the conversion of T4 (3,3′,5,5′-tetraiodothyronine) to T3 in cells is mediated by iodothyronine deiodinases enzymes (DIOs). DIOs are selenocysteine containing enzymes and are classified into three types (DIO1, DIO2 and DIO3). DIO1 catalyzes the outer-ring deiodination (ORD; T3 formation) and inner-ring deiodination (IRD; rT3 formation) reactions, involving in the activation (T4 to T3 conversion) and inactivation (T4 to rT3 conversion), respectively. DIO2 and DIO3 catalyse the ORD and IRD reactions, respectively. This homeostasis is regulated tightly and any deviation would lead to diseases like hyperthyroidism or hypothyroidism. Recently it is of interest to many research groups to develop iodothyronine deiodinase mimics and we have developed naphthalene-based peri-substituted thioselenol pair at 1,8-positions (1.25), which remove iodine selectively from inner-ring of T4. When selenium atom is substituted in place of sulfur (selenol-selenol pair; 1.26), the deiodination activity was ca. 90 times faster than with 1.25. This thesis deals with various aspects of the effect of substituents on the naphthalene-1,8-diselenol and solvent effect on the thyroid hormone deiodination by naphthalene-based iodothyronine deiodinase mimics. Figure 1. (A) Deiodination reactions by DIOs. (B) Chemical structure of 1.25 and 1.26. The thesis consists of five chapters. The first chapter provides a general overview about sialoproteins, thyroid hormone biosynthesis, thyroid hormone metabolism, halogen bonding, iodothyronine deiodinase mimics and proposed mechanisms for the deidoination of thyroid hormones. This chapter also introduces peri-naphthalene-1,8-diselenol (1.26), which is the key compound in this thesis and discusses about proposed mechanism for the deiodination of thyroxine involving co-operative halogen bonding and chalcogen bonding mechanism. Figure 2. (A) TH action. (B) Proposed mechanism for the deiodination of T4 by 1.26 involving cooperative halogen bonding and chalcogen bonding. Chapter 2 discusses about the synthesis, characterization and deiodination activity of a series of naphthalene-based peri-substituted-1,8-diselenols (Figure 3). These diselenols regioselectivity remove iodine from inner ring of thyroxine and other thyroid hormones, (T3 and 3, 5-T2). Substitution with different groups on the naphthalene ring did not change the regioselectivity of deiodination, indicating that the deiodination activity does not depend on the nature of substituents. Secondary or tertiary amine side chain group attached at the 2nd position of the naphthalene ring showed better activity. It is due to the secondary interaction, which facilitates the iodine removal. It was further confirmed with the substitutions at the 4th position of the ring to discriminate the possibility of electronic effect. The higher deiodination rate owing to the t-butyl group at second position of the ring also suggests that the steric effect may also play a role in the deiodination reaction (Figure 4). It is proposed that peri substituted naphthalene-1,8-diselenols remove iodine from thyroid hormones through halogen bonding-chalcogen bonding mechanism (Figure 2). The investigation of Se···Se bond distance from the crystal structures and through DFT calculation and NMR experiment showed that the stronger chalcogen bond could be the reason for the increase in the reactivity observed with substituted peri-naphthalene-1,8-diselenols. Figure 3. peri-substituted naphthalene-1,8-diselenols used for the study. Figure 4. Relative deiodinase activity of substituted-peri-naphthalene-1,8-diselenols with T4. In Chapter 3, we have discussed about the effect of chalcogen atom substitution in a series of deiodinase mimics on the deiodination of thyroid hormones. Moving from thiol-selenol pair (1.25) to selenol-selenol pair (1.26) in naphthalene based peri-substituted mimics, an increase in the activity was observed. In this chapter, we have shown that substituting with tellurium, as tellurium-thiol pair (3.3) and ditellurol (3.4) increases the reactivity of deiodination to several times and also regioselectivity of deiodination is changed from IRD in the case of 1.26 to both IRD and ORD for 3.3 and 3.4. The presence of two tellurol moieties (3.4) or a thiol-tellurol pair (3.3) can mediate sequential deiodination of T4, to produce all the possible thyroid hormone derivatives under physiologically relevant conditions (Figure 5). This study provided the first experimental evidence that the regioselectivity of the thyroid hormone deiodination is controlled by the nucleophilicity and the strength of halogen bond between the iodine and chalcogen atoms. Figure 5. (A) HPLC chromatograms of deiodination reaction of T4 with 3.3 and 3.4. (B) Chemical structure of 3.3 and 3.4. (C) Sequential deiodination reaction of T4 by 3.3 and 3.4. Chapter 4 describes the effect of alkyl conjugation at 4′-OH position of THs on the deiodination by iodothyronine mimics. In addition to the deiodination, iodothyronines undergo conjugation with sulfate and glucuronic acid group at 4′-hydroxyl position. Conjugation alters the physico-chemical properties of iodothyronines. For example, it is known that sulfate conjugation increases the rate of deiodination to a large extend. We have conjugated alkyl group at 4′-hydroxyl position of iodothyronines and investigated the deiodination reactions with reported peri-substituted naphthalene-1,8-diselenols. We observed that similar to sulfated thyroid hormones O-methylthyroxine also undergoes both phenolic and tyrosyl ring deiodination reactions and overall the rate of deiodination is increased at least by 5 times as compared with T4 under identical conditions. The phenolic iodine removal is favored by conjugation as compared to the tyrosyl ring iodine, which is similar to the observation made for T4S. Interestingly, when the acetamide group is conjugated at 4′-OH position, the regioselectivity of deiodination is changed exclusively to 5′-iodine. DFT calculations show that the positive potential on the iodine increase upon conjugation, which leads to stronger halogen bonding interaction with selenol, might be the reason for the change in the regioselectivity of deiodination. Figure 6. (A) HPLC chromatogram of deiodination reaction of T4(Me) with 1.26. (B) Initial rate comparison of T4 and T4(Me).(C) HPLC chromatogram of deiodination reaction of T4(AA) with 1.26 showing the formation of T3(AA) (ORD product). (D) Electron potential map of T4, T4(Me) and T4(AA) showing the increase in electro positive potential on 5′-iodine upon conjugation. Chapter 5 deals with the solvent effect on the deiodination reactions of THs by iodothyronine deiodinase mimics. As discussed in the earlier chapters, the deiodination reaction of thyroxine by naphthalene based-1,8-diselenols under physiological conditions produce, rT3 (IRD) as the only observable products. Surprisingly, when the deiodination reaction was performed in DMF or DMSO in the presence of 1.26, the regioselectivity of reaction was changed and the formation of both T3 (ORD) and rT3 was observed. In DMF or in DMSO, the deiodination reactivity of 1.26 was found to be 1000 fold higher than the reaction performed in phosphate buffer at pH 7.4. Figure 7. (A) HPLC chromatogram for the deiodination reaction of T4 in DMF by 1.26 showing both IRD and ORD. (B) A comparison of initial rate for the deiodination reactions of T4, T3 and 3,5-T2 in DMF and in DMSO by 1.26. (C) HPLC chromatograms for the deiodination reaction of T4 in DMF by 1.26 in the presence of TEMPO, showing the inhibition of deiodination (i) 0 mM TEMPO (ii) 10 mM of TEMPO (iii) 30 mM TEMPO. (D) HPLC chromatograms for the deiodination reaction of T4 in DMSO by 1.26 in the presence of TEMPO showing the inhibition of deiodination (i) 0 mM TEMPO (ii) 10 mM of TEMPO (iii) 30 mM TEMPO. 3,5-DIT was not denominated under physiological conditions, however, in DMF and in DMSO, 3,5-DIT was deiodinated by 2.4 to produce 3-MIT. We also observed that the control reactions in DMF or DMSO also showed a little deiodination activity. The very high reactivity observed in the presence of DMF or DMSO implied that the mechanism of denomination in these solvents may be different. It has been reported that DMSO or DMF radicals can be formed with small amounts of a base. Reaction mixture consisting of NaBH4 (for generating selenol from diselenide) and NaOH (T4 solution) may facilitate the radical formation. We also performed the reaction in the presence of TEMPO (free radical scavenger) and observed the inhibition of deiodination reaction. However, it is not clear whether the radical pathway could be one of the possible mechanisms of deiodination in these solvents by compounds 1.26 and 2.4. Further studies are required to propose a radical mechanism in different solvents such as DMF and DMSO.
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Antioxidant Activity Of The Anti-Inflammatory Compound Ebselen And Its Analogues : Role Of Nonbonded InteractionsSarma, Bani Kanta 07 1900 (has links)
Although considered as a poison for long time, the importance of selenium as an essential trace element is now well recognized. In proteins, the redox active selenium moiety is incorportated as selenocysteine (Sec), the 21st amino acid. In mammals, selenium exerts its redox activities through several selenocysteine-containing enzymes, which include glutathione peroxidase (GPx), iodothyronine deiodinase (ID) and thioredoxin reductase (TrxR). Although these enzymes have Sec in their active sites, they catalyze completely different reactions and their substrate specificity and cofactor or co-substrate systems are significantly different. The most widely studied selenoenzyme GPx protects various organisms from oxidative stresses by catalyzing the reduction of hydroperoxides by using glutathione (GSH) as cofactor. The chemical aspects of the reduction of hydroperoxide by GPx have been extensively studied with the help of synthetic selenium and tellurium compounds. For example, 2-phenyl, 1, 2-benzoisoselenazol-3(2H)-one, commonly known as ebselen exhibits significant GPx activity by using GSH as cofactor. The anti-inflammatory, antiatherosclerotic and cytoprotective properties of ebselen have led to the design and synthesis of nex GPx mimics for potential therapeutic applications.
In the first chapter, the importance of selenium in biochemistry in general and the function of selenoenzyme GPx and its synthetic mimics in particular are discussed. In the second chapter, the importance of ebselen as a GPx mimic and how thiol exchange reaction in the selenenyl sulfide intermediate deactivates its catalytic cycle and the possible ways to overcome thiol exchange reaction are described. The third chapter deals with the first synthetic chemical model that effectively mimics the unusual cyclization of sulfenic acid to a sulfenyl amide in protein Tyrosien Phosphatase 1B(PTP1B). PTP1B is a cysteine containing enzyme where the sulfenic acid (PTP1B-SOH) intermediate produced in response to its oxidation by H2O2 is rapidly converted into a sulfenyl amide species, in which sulfur atom of the catalytic cysteine is covalently bonded to the main chain nitrogen of an adjacent serine residue. This unusual protein modification in PTP1B has been proposed to protect the sulfur centre from irreversible oxidation to sulfinic acid and and sulfonic acids. In the fourth chapter, it is shown that not only the catalytic efficiency of ebselen but also its phosphatase like behavior is important for its antioxidant activity. Ebselen is regenerated from selenenic acid (R-SeOH) under a verity of conditions, which protects its selenium centre from irreversible oxidation and thus reduces its toxicity. The fifth chapter deals with spirodizaselenurane and Spirodiazatellurane. Although the chemistry of spirodioxyselenuranes and spirodiazasulfuranes has been studied extensively due to their interesting structural and stereochemical properties, there is no example of stable spirodiazaselenurane and its tellurium analogues. In the fifth chapter, the synthesis, structure and GPx-like activity of the spirodizzaselenurane and spirodiazatellurane are discussed.
In summary, the synthetic sulfenic acids and seleneric acids undergo cyclization to their corresponding sulfenyl amides and selenenyl amides and thus protect their sulfur and selenium centers from irreversible inactivation. We have also observed that selenoxides and telluroxides with nearby amide moieties undergo cyclization to their corresponding cyclic spiro compounds. This unusual transformation of sulfenic acids has been recently discovered in PTP1B. As the redox regulation cycle of PTP1B and the catalytic cycle of GPx are similar we believe that GPx may involve a selenenyl amide intermediate in its catalytic cycle.
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Synthetic Antioxidants : Structure-Activity Correlation Studies Of Glutathione Peroxidase Mimics And Peroxynitrite ScavengersBhabak, Krishna Pada 07 1900 (has links)
Reactive oxygen species (ROS) such as superoxide radical anion (O2•¯), hydroxylradical (OH•), hydrogen peroxide (H2O2) and peroxynitrite (ONOO-) that are produced during the metabolism of oxygen under oxidative stress in aerobic organisms destroy several key biomolecules and lead to a number of disease states. Mammalian systems possess several effective defense mechanisms including antioxidant enzymes to detoxify these ROS. The selenocysteine-containing Glutathione peroxidase (GPx) is particularly an efficient enzyme in the detoxification of H2O2 and other hydroperoxides by using glutathione (GSH) as cofactor. The chemistry at the active siteof GPx has been extensively investigated with the help of synthetic selenium compounds. Although the anti-inflammatory compound ebselen(2-phenyl-1,2-benzoisoselenazol-3(2H)-one) is undergoing phase III clinical trial as antioxidant, the chemistry of ebselen is still not understood.
The present study on a number of ebselen derivatives with various N-substitutions reveals that the substitution at the N atom is important for the antioxidant activity. This study also suggests that the nature for thiol cofactor has a dramatic effect on the GPx activity of ebselen derivatives. It has been shown that ebselen exhibits very poor catalytic activity in the presence of aromatic thiols mainly due to strong Se….O nonbonded interactions that lead to extensive thiol exchange reactions in the selenenyl sulfide intermediate. To prevent the se….O interactions, a series of tertiary amide-based diselenides have been synthesized along with their secondary amide counterparts.
Detailed structure-activity correlation studies reveal that the GPx-like activity of the sec-amide-based compounds can be significantly enhanced by the substitution at the free-NH group of sec-amide functionality. The N,N-dialkylbenzylamine-based diselenides exhibit their catalytic activities via the generation of selenols which was confirmed by the reaction with anti-arthritic gold(I) compounds. Interestingly, the replacement of the hydrogen atom at the 6th position of the benzene ring of N,N-dialkylbenzylamine-based diselenides by a methoxy group prevents the thiol exchange reactions mainly be weakening the Se…N interactions and thus enhances the GPx activity. On the other hand, the catalytic activity of the tert-amine-based diselenides can also be increased by replacing the tert-amino groups with the corresponding sec-amine moieties. It has been observed that the basic amino group in the amine-based diselenides deprotonates the selenol and also the thiol cofactor, which is crucial for the higher catalytic activities of the amine-based compounds.
Peroxynitrite (PN, ONOO), a strong nitrating agent, is known to inactivate a number of proteins, enzymes and other biomolecules by nitration of tyrosine residues. In this study, we have shown that the commonly used antithyroid drugs and their analogues inhibit protein tyrosine nitration. This study reveals that antithyroid agents having PN scavenging activity may be beneficial of hyperthyroidism as these compounds may protect the thyroid gland from nitrative or nitrosative stress.
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Deiodination of Thyroid Hormones by Iodothyronine Deiodinase MimicsManna, 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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