Global ETD Search

151	A sincronização noradrenérgica e o papel da insulina na modulação da síntese da melatonina pela glândula pineal de ratos. / Noradrenergic synchronization and the role of insulin on the modulation of melatonin synthesis in cultured rat pineal gland. Garcia, Rodrigo Antonio Peliciari 05 June 2008 (has links) A glândula pineal de mamíferos sintetiza o hormônio melatonina exclusivamente durante o período noturno. A síntese é regulada primordialmente pela via retino-hipotalâmico-pineal e modulada por vários fatores, incluindo o sistema peptidérgico. Assim, o papel da insulina na regulação da síntese de melatonina foi estudado a partir da realização de culturas de glândulas pineais estimuladas com noradrenalina, insulina e noradrenalina associada à insulina, em culturas temporizadas ou não pela noradrenalina, avaliando: a produção de melatonina por HPLC com detecção eletroquímica; as atividades das enzimas envolvidas na síntese da melatonina, por radiometria; assim como, a expressão gênica das enzimas quantificada por Real-Time PCR. Os resultados sugerem uma interação entre as vias de sinalização da noradrenalina e da insulina, com a respectiva potencialização da síntese da melatonina, induzida por noradrenalina, observada pela adição da insulina, efeito esse, que se dá, provavelmente através de mecanismos pós-transcricionais. / The mammalian pineal gland synthesizes the neurohormone melatonin exclusively during the dark phase. Its synthesis is primarily regulated via a retino-hypothalamic-pineal pathway and modulated by many factors, including the peptidergic system. Thus, the role of insulin on the regulation of melatonin synthesis was studied using cultured gland treated with norepinephrine, insulin and norepinephrine associated to insulin. The cultures were also synchronized or not by norepinephrine. Melatonin content was assayed by HPLC (High Performance Liquid Chromatography) with electrochemical detection, melatonin synthesis enzymes activities by radiometry and enzymes gene expressions by Real-Time PCR. The results suggest an interaction between norepinephrine and insulin signaling pathway, with insulinic potentialization on melatonin synthesis norepinephrine-mediated, and this effect, seems to accurs potentially through post-transcriptional events. Arilalquilamina-N-acetiltransferase Arylelkylamine-N acetyltransferase Glândula pineal Insulin Insulina Melatonin Melatonina Noradrenalina Norepinephrine Pineal gland Triptofano hidroxilase Tryptophan hydroxylase
152	Efeitos do treinamento físico sobre a síntese/armazenamento de noradrenalina em arteríolas musculares esqueléticas e renais de ratos hipertensos espontâneos / Training induced effects on noradrenaline synthesis/storage within the skeletal muscle and renal arterioles in spontaneously hypertensive rats Marina Tuppy 10 September 2007 (has links) Investigamos os efeitos do treinamento físico (T) sobre a densidade da tirosina hidroxilase (TH) em arteríolas e adrenais (respostas neuro-hormonais). SHR machos foram treinados (55% da capacidade máxima) ou mantidos sedentários (S). Após o registro da PA e FC basais, foram anestesiados para obtenção dos tecidos (músculos locomotores: sóleo, gastrocnêmio, grácil; não-locomotor: temporal; rins e supra-renais) para o Western Blot ou imunohistoquímica. O T aumentou a capacidade física (+77%) e reduziu PA e FC (-6% e -10%, p<0.05). Houve aumento da TH imunorreatividade nos músculos locomotores (+57%, p<0.05), com aumento discreto no temporal (+24%, p>0.05), sem alteração nos rins. Houve normalização da razão parede/luz apenas nas arteríolas de músculos locomotores, sem alteração da TH nas supra-renais. O T aumenta a síntese/armazenamento da noradrenalina nas arteríolas musculares esqueléticas (resposta neural), uma compensação à redução da razão p/l para manutenção do fluxo sanguíneo local. A não alteração de TH no temporal sugere que a resposta neural é modulada por fatores locais / We investigated the effects of training (T) on tyrosine hydroxylase (TH) density in arterioles and adrenals (neuro-hormoral responses). Male SHR were submitted to treadmill T (55% of maximal capacity) or kept sedentary (S). After AP and HR recordings, rats were anesthetized and tissues (soleus, gastrocnemius red, gracilis = locomotor; temporalis = non-locomotor muscle; kidney and adrenals) collected for Western Blot and immunohistochemistry. T improved treadmill performance (+77%) and reduced AP and HR (-6% and -10%, p<0.05). TH immunoreactivity was increased in locomotor muscles (+57%, p<0.05) with smaller changes on temporalis (+24%, p>0.05) without any change on kidneys. Enlarged arterioles wall/lumen ratio was reduced only in locomotor muscles; there was no change on adrenals TH content. T increases noradrenaline synthesis/storage on skeletal muscles arterioles, which represents a compensatory neural response to T-induced structural remodeling in order to maintain a near normal local flow. Absence of changes on temporalis TH suggests that neural response is modulated by local factors Arteríolas Hidroxilase Hipertensão SHR Sistema Nervoso simpático Tirosina Treinamento Físico Arterioles Hypertension Physical training SHR Simpathetic system Tyrosine hydroxylase
153	Effect of Toxaphene on Collagen Synthesis in Fish Tissue: Organ Culture Studies and Prolyl Hydroxylase Activity Assay Luke, Charles Franklin 01 May 1981 (has links) Toxaphene is reported to cause defects in the collagen of fish. Chronic exposure to toxhaphene weakens the backbone of fish by decreasing the amount of collagen and usually increasing the amount of calcium in the bone which results in a more brittle and fragile bone. We investigated the possible direct action of toxaphene on collagen synthesis by exposing vertebral and swim bladder organ cultures obtained from unexposed rainbow trout (Salmo gairdneri) fingerlings to the same lot of toxaphene found to cause this defect in vivio. Collagen produced by these organ cultures was measured by: (1) total 3H-proline incorporated into the matrix; (2) 3H-proline released during collagenase digestion of acid-precipitated protein; (3) 3H-hydroxyproline extracted from the acid hydrolysate, and (4) tritiated water produced during the hydroxylation of 4-3H-proline. At a relatively high concentration of toxaphene (2.4 mM) these indices of collagen production were reduced, but this was probably caused by a decrease in tissue viability rather than by a direct affect on collagen synthesis. At 240 μM cellular protein synthesis was reduced. Generally no effects were found at toxaphene concentrations below 240 μM. From these studies it was concluded that toxaphene does not have a direct inhibitory effect upon collagen production at the tissue level. For comparison to the in vivo were measured. All three of these parameters were significantly reduced in comparison to controls (α = 0.05) in those fish exposed to the highest concentration of toxaphene (200 ng/1). fish exposed to 150 ng/l toxaphene also had reduced prolyl hydroxylase activity. These results indicated that vertebral prolyl hydroxylase activity may be a sensitive indicator of toxaphene exposure in fish, and inhibition of that enzyme may be involved in the mechanism of toxaphene-induced collagen effects. effect toxaphene collagen synthesis fish tissue organ culture studies prolyl hydroxylase activity assay Animal Sciences Dairy Science Life Sciences
154	Etude des souris invalidées pour le gène Tph1: Implication de la sérotonine dans l'érythropoïèse. Hatia, Sarah 21 September 2011 (has links) (PDF) L'érythropoïèse est le processus de formation des globules rouges (GR) ayant lieu principalement dans la moelle osseuse. Il débute par l'engagement de cellules souches hématopoïétiques vers la lignée érythroïde, qui donnent lieu à des progéniteurs, puis à des précurseurs érythroïdes. Des changements morphologiques accompagnent la différenciation érythroïde, incluant une réduction de la taille des cellules, l'acquisition d'hémoglobine et finalement, l'expulsion du noyau qui survient au stade réticulocytes. Ces réticulocytes sont à l'origine des GR retrouvés dans la circulation sanguine. L'anémie est définie par une diminution de la teneur en hémoglobine dans le sang et peut être causée par une diminution de la production de GR, ou par une augmentation de leur destruction. La sérotonine (5-HT) est depuis longtemps connue comme un neurotransmetteur dans le système nerveux central (SNC), où elle est impliquée dans de nombreuses fonctions. Sa disponibilité dépend de l'expression de la tryptophane hydroxylase (TPH), dont une étude récente a révélé l'existence de deux isoformes, la TPH2 exprimée dans le SNC et la TPH1 en périphérie. Cette découverte a ravivé l'intérêt d'étudier les fonctions potentielles de la 5-HT en dehors du SNC. De plus, des rôles non suspectés de la 5-HT dans de nombreux systèmes physiologiques en périphérie ont été révélés par la caractérisation du modèle murin KO pour la Tph1 (Tph1-/-). Dans ce manuscrit, nous présentons des données in vivo, montrant que les souris Tph1-/- présentent une érythropoïèse inefficace. Le défaut majeur survient dans la moelle osseuse, où l'absence de 5-HT altère la progression des précurseurs érythroïdes, qui expriment les récepteurs 5-HT2A et 5-HT2B, vers la différenciation terminale. Ces précurseurs expriment également la Tph1, suggérant une synthèse locale de 5-HT. De plus, des cultures in vitro nous ont permis de démontrer l'action directe de la 5-HT sur les précurseurs érythroïdes, par l'ajout de 5-HT qui augmente la capacité proliférative des cellules issues des souris sauvages et mutées. D'autre part, les GR issus des souris Tph1-/- sont plus sensibles à la phagocytose par les macrophages et ont une durée de vie significativement réduite par rapport à des GR sauvages. Cette dégradation augmentée des GR associée à l'érythropoïèse inefficace dans la moelle osseuse, conduisent à un phénotype d'anémie macrocytaire des souris Tph1-/-. Lorsqu'elles vieillissent, les souris développent une splénomégalie, due à une érythropoïèse accrue dans la rate. L'ensemble de nos résultats démontre que la 5-HT est un facteur clef dans la production et la survie des GR. sérotonine tryptophane hydroxylase 1 anémie érythropoïèse moelle osseuse modèle murin
155	X-ray characterization of PaPheOH, a bacterial phenylalanine hydroxylase Ekström, Fredrik January 2003 (has links) <p>Many human diseases are associated with the malfunction of enzymes in the aromatic amino acid hydroxylase family, e.g. phenylketonuria (PKU), hyperphenylalaninemia (HPA), schizophrenia and Parkinson's disease. The family of aromatic aminoacid hydroxylases comprises the enzymes phenylalanine hydroxylase (PheOH), tyrosine hydroxylase (TyrOH) and tryptophane hydroxylase (TrpOH). These enzymes require the cofactor (6R)-L-erythro-5,6,7,8-tetrahydrobiopterin (BH4) and atomic oxygen. In eukaryotes, the aromatic amino acid hydroxylases share the same organization with a N-terminal regulatory domain, a central catalytic domain and a C-terminal tetramerization domain. Aromatic amino acid hydroxylases that correspond to the core catalytic domain of the eukaryotic enzymes are found in bacteria. The main focus of this thesis is the structural characterization of a phenylalanine hydroxylase from the bacterium Pseudomonas aeruginosa (PaPheOH). </p><p>To initiate the structural characterization, the active site environment was investigated with X-ray absorption spectroscopy (XAS). The experimental data support a model where the active site iron is coordinated by four oxygen atoms and two nitrogen atoms. We suggest that two water molecules, His121, His126 and Glu166 coordinates the active site iron. In this model, Glu166 provides two of the oxygen atoms in a bidentate binding geometry. EXAFS and XANES studies indicate that structural rearrangements are induced in the second and third coordination shells in samples of PaPheOH with BH4 and/or L-Phe. </p><p>The 1.6 Å X-ray structure of PaPheOH shows a catalytic core that is composed of helices and strands in a bowl-like arrangement. The iron is octahedrally coordinated, by two water molecules and the evolutionary conserved His121, His126 and Glu166 that coordinates the iron with bidentate geometry. The pterin binding loop of PaPheOH (residue 81-86) adopts a conformation that is displaced by 5-6 Å from the expected pterin binding site. Consistent with the unfavourable position of the pterin binding loop is the observation that PaPheOH has a low specific activity compared to the enzymes from human and Chromobacterium violaceum. </p><p>The second part of this thesis focus on the crystallization and structure determination of the actin binding domain of a-actinin (ABD). a-Actinin is located in the Z-disc of skeletal muscle were it crosslinks actin filaments to the filamentous protein titin. The ABD domain of a-actinin crystallizes in space group P21 with four molecules in the asymmetric unit. The structure of the ABD domain has been solved to a d-spacing of 2.0 Å. The two CH-domains of ABD is composed of 5 a-helices each. The a-helices fold into a closed compact conformation with extensive intramolecular contacts between the two domains.</p> Biochemistry PaPheOH PheOH PAH phhA phenylalanine hydroxylase protein crystallography a-actinin microcrystal ABD CH-domain Biokemi Biochemistry Biokemi
156	Regulation of Vitamin D 25-hydroxylases : Effects of Vitamin D Metabolites and Pharmaceutical Compounds on the Bioactivation of Vitamin D Ellfolk, Maria January 2008 (has links) A 700bp portion of the promoter of CYP2D25, the porcine microsomal vitamin D 25-hydroxylase was isolated and sequenced. The computer analysis of the sequence revealed the existence of a putative VDRE at 220 bp upstream of the transcription start site. A CYP2D25 promoter-luciferase reporter plasmid was constructed in order to study the transcriptional regulation of the gene. Treatment with the vitamin D metabolites calcidiol and calcitriol suppressed the promoter, provided that the nuclear receptors VDR and RXR were overexpressed. Phenobarbital was also capable of suppressing the promoter if the nuclear receptors PXR or CAR were overexpressed. The 25-hydroxylases are not expressed solely in liver but in a wide array of other organs as well. It is therefore possible at least in theory to study the vitamin D 25-hydroxylation in human subjects using cells from extrahepatic organs, from which biopsy retrieval is easier than from the liver. Dermal fibroblasts are frequently used to study different pathological conditions in human subjects and they are easy to come by. Dermal fibroblasts were shown to express two vitamin D 25-hydroxylases: CYP27A1 and CYP2R1. The expression pattern of CYP2R1 displayed considerable interindividual variation. The fibroblasts were also capable of measurable vitamin D 25-hydroxylation, which makes dermal fibroblasts a possible tool in studying vitamin D 25-hydroxylation in human subjects. Little is known about the regulation of expression and activity of the human vitamin D 25-hydroxylases. Therefore dermal fibroblasts – expressing CYP2R1 and CYP27A1 – and human prostate cancer LNCaP cells, that express CYP2R1 and CYP2J2, were treated with calcitriol and phenobarbital and efavirenz, two drugs that give rise to vitamin D deficiency. Treatment decreased the mRNA levels of CYP2R1 and CYP2J2 provided that the treated cells also expressed the necessary nuclear receptors. CYP27A1 did not respond to any of the treatments. The treatments also managed to decrease the 25-hydroxylating activity of the cells. The results show that vitamin D 25-hydroxylases can be regulated by both endogenous and xenobiotic compounds. CYP2D25 vitamin D 25-hydroxylase transcriptional regulation vitamin D CYP2R1 CYP2J2 CYP27A1 phenobarbital efavirenz fibroblast LNCaP Pharmaceutical biochemistry Farmaceutisk biokemi
157	Locus Coeruleus Neurons in Autonomic Regulation of Breathing: Insight from a Mouse Model of Rett Syndrome Zhang, Xiaoli 26 April 2010 (has links) Patients with Rett Syndrome (RTT) show severe breathing disorders in addition to other neuropathological features, contributing to the high incidence of sudden unexplained death and abnormal brain development. However, the molecular and cellular mechanisms underlying the breathing disorders are still unknown. Recent studies indicate that the dysfunction of brainstem norepinephrine (NE) systems are closely associated with breathing disorders in RTT patients as well as its mice model, the Mecp2-null (Mecp2â”€/Y) mice. This as well as the fact the major group of NE-ergic neurons in the locus coeruleus (LC) is CO2 chemosensitive suggests that the breathing disorders in RTT may be related these LC neurons. To test this hypothesis, we took a multidisciplinary approach and systematically studied these neurons using molecular biology, in-vitro brain slices, acutely dissociated neurons, immunocytochemistry, and whole-body plethysmograph. To facilitate the electrophysiological studies, we developed a new strain of transgenic mice with GFP expression selectively in the LC neurons of both WT and Mecp2â”€/Y mice. Breathing activity of the Mecp2â”€/Y mice showed selective disruptions in responses to mild hypercapnia. The defect was alleviated with the NE uptake blocker desipramine, suggesting the involvement of NE in central CO2 chemosensitivity. In the LC region, the expressions of tyrosine hydroxylase (TH) and dopamine beta-hydroxylase (DBH) at both protein and mRNA levels reduced by ~50% in Mecp2â”€/Y mice. No evidence was found for selective deficiency in TH- or DBH-containing neurons in Mecp2â”€/Y mice, and no major loss of NE-ergic LC cells were found, indicating that the NE defect is likely to result from deficient expression of biosynthetic enzymes rather than a loss of neurons in the LC. Several intrinsic membrane properties were abnormal in Mecp2â”€/Y LC neurons in comparison to wild type cells, including stronger inward rectification, shorter time constant, extended action potential duration, smaller amplitude of medium afterhyperpolarization (AHP) and over-expression of fast AHP. These abnormalities seem to be associated with the altered K+ and Na+ currents. Most importantly, Mecp2â”€/Y LC neurons displayed defective CO2 chemosensitivity in agreement of in vivo CO2 response, likely due to excessive expression of the homomeric Kir4.1 channel. Thus, it seems that the global effect of MeCP2 on the A6 NE system contributes to the impaired systemic CO2 response as well as the breathing irregularities in Mecp2â”€/Y mice. Such an alteration allowed CO2 to be detected only when hypercapnia became severe, leading to periodical hyper- and hypoventilation. These findings not only provide a novel etiology for the breathing disturbances of Mecp2â”€/Y mice but also show direct evidence for the first time on a molecular mechanism for the central CO2 chemosensitivity. Dopamine Î²-hydroxylase CO2 chemosensitivity Breathing rhythm Locus coeruleus Norepinephrine Monoaminergic Rett syndrome Intrinsic membrane properties Brainstem Biology, general
158	The Effects Of Phenolic Compound Tannic Acid On Phase Ii And Cytochrome P450 Dependent Enzymes In Rabbit Liver And Kidney Karakurt, Serdar 01 June 2008 (has links) (PDF) Cancer is the second leading cause of death after cardiovascular diseases in the world. Many of the chemical carcinogens need metabolic activation that catalyzed by cytochrome P450 and Phase II enzymes in order to exert their genotoxic and carcinogenic effects. Hence one possible mechanism is that phenolic compounds may alter anticarcinogenic effects is through an interaction with these enzymes either by the inhibition or activation of certain forms, leading to a reduced production of the ultimate carcinogen. Therefore anti-carcinogen activity of tannic acid, a hydrolyzable plant polyphenol, has a crucial importance to prevent conversion of pro-carcinogens to their carcinogenic form. Tannic acid is produced from secondary metabolism of plants and is found in edible vegetables, fruits and nuts, especially tea, cocoa, coffee and wine. In the present work, modulation of rabbit liver and kidney microsomal P450 dependent aniline 4-hydroxylase, N-nitrosodimethylamine N-demethylase and p-nitrophenol hydroxylase activities and cytosolic phase II enzymes / glutathione S-transferase (GST), NAD(P)H:quinone oxidoreductase:1 (NQO1) were studied in the presence of tannic acid at concentrations ranging from 0.5 &micro / M to 150 &micro / M in the reaction medium. The results obtained in this study were shown that tannic acid significantly inhibited the activities of p-nitrophenol hydroxylase, aniline 4-hydroxylase, NDMA N-demethylase, glutathione S-transferase, NAD(P)H:quinine oxidoreductase 1. Tannic acid was found to be the most potent inhibitor of cytosolic glutathione S-transferase with IC50 of 0.33 &micro / M and the least potent inhibitor of microsomal aniline 4-hydroxylase.with IC50 of 60.26 &micro / M. Effect of tannic acid on enzyme activities was further studied for both mode and type of inhibition. For this purpose various concentrations of the substrate were examined at various tannic acid concentrations. Lineweaver-Burk and Dixon plots were then generated from the resulting data sets. The Km value and inhibition constants (KI) were determined from double reciprocal and Dixon plot of the enzyme activity versus substrate and inhibitor concentration, respectively. Tannic acid was shown to be a noncompetitive inhibitor for liver cytosolic GST, NQO1 and microsomal aniline 4- hydroxylase enzymes with KI of 0.3 &micro / M, 41 &micro / M and 54.7 &micro / M, respectively. On the other hand, in kidney tissues, tannic acid was an uncompetitive inhibitor of cytosolic GST, while it was noncompetitive inhibitor for cytosolic NQO1 with a KI of 12.6 &micro / M. These results indicate that tannic acid may modulate cytochrome P450 dependent and Phase II enzymes and influence the metabolic activation of xenobiotics mediated by these enzymes. QD Biochemistry 415-436 GST, NQO1, Rabbit, Liver, Kidney.
159	Cyanide and central nervous system : a study with focus on brain dopamine Cassel, Gudrun January 1993 (has links) The brain is a major target site in acute cyanide intoxication, as indicated by several symptoms and signs. Cyanide inhibits the enzyme cytochrome oxidase. This inhibition causes impaired oxygen utilization in all cells affected, severe metabolic acidosis and inhibited production of energy. In this thesis, some neurotoxic effects of cyanide, in particular, the effects on dopaminergic pathways were studied. In a previous study, decreased levels of striatal dopamine and HVA were found after severe cyanide intoxication (5-20 mg/kg i.p.). However, increased striatal dopamine were found in rats showing convulsions after infusion of low doses of cyanide (0.9 mg/kg i.v.), at the optimal dose rate (the dose rate that gives the treshold dose). Increased striatal dopamine synthesis was observed in rats after cyanide treatment and in vitro. Furthermore, in rat, as well as in pig striatal tissue, cyanide dose- dependently increased the oxidative deamination of 5-HT (MAO-A) and DA (MAO-A and -B) but not that of PEA (MAO-B). Thus cyanide affects both the synthesis and metabolism of dopamine. In rats, sodium cyanide (2.0 mg/kg, i.p.) decreased the striatal dopamine Dj- and D2-receptor binding 1 hour after injection. Increased extracellular levels of striatal dopamine and homovanillic acid were also shown after cyanide (2.0 mg/kg; i.p.). DOPAC and 5-HIAA were slightly decreased. This indicates an increased release or an extracellular leakage of dopamine due to neuronal damage caused by cyanide. Thus the effects of cyanide on dopamine Dj- and D2~receptors could in part be due to cyanide-induced release of dopamine. Because of reported changes in intracellular calcium in cyanide-treated animals, the effects of cyanide on inositol phospholipid breakdown was studied. Cyanide seemed not to affect the inositol phospholipid breakdown in vitro. The effects of cyanide on the synthesis and metabolism of brain GAB A were also examined. A decreased activity of both GAD and GAB A-T were found in the rat brain tissue. The reduced activity of GAB A-T, but not that of GAD returned to the control value after adding PLP in the incubation media. The cyanide-produced reduction of GABA levels will increase the susceptibility to convulsions, and could partly be due to GAD inhibition. In conclusion, cyanide affects the central nervous system in a complex manner. Some effects are probably direct. The main part, however, appears to be secondary, e.g. hypoxia, seizures, changes in calcium levels or transmitter release produced by cyanide. / <p>Diss. (sammanfattning) Umeå : Umeå universitet, 1993, härtill 7 uppsatser</p> / digitalisering@umu CNS cyanide dopaminergic system convulsions receptor binding tyrosine hydroxylase monoamine oxidase extracellular release inositol phosphate GABA GAD
160	X-ray characterization of PaPheOH, a bacterial phenylalanine hydroxylase Ekström, Fredrik January 2003 (has links) Many human diseases are associated with the malfunction of enzymes in the aromatic amino acid hydroxylase family, e.g. phenylketonuria (PKU), hyperphenylalaninemia (HPA), schizophrenia and Parkinson's disease. The family of aromatic aminoacid hydroxylases comprises the enzymes phenylalanine hydroxylase (PheOH), tyrosine hydroxylase (TyrOH) and tryptophane hydroxylase (TrpOH). These enzymes require the cofactor (6R)-L-erythro-5,6,7,8-tetrahydrobiopterin (BH4) and atomic oxygen. In eukaryotes, the aromatic amino acid hydroxylases share the same organization with a N-terminal regulatory domain, a central catalytic domain and a C-terminal tetramerization domain. Aromatic amino acid hydroxylases that correspond to the core catalytic domain of the eukaryotic enzymes are found in bacteria. The main focus of this thesis is the structural characterization of a phenylalanine hydroxylase from the bacterium Pseudomonas aeruginosa (PaPheOH). To initiate the structural characterization, the active site environment was investigated with X-ray absorption spectroscopy (XAS). The experimental data support a model where the active site iron is coordinated by four oxygen atoms and two nitrogen atoms. We suggest that two water molecules, His121, His126 and Glu166 coordinates the active site iron. In this model, Glu166 provides two of the oxygen atoms in a bidentate binding geometry. EXAFS and XANES studies indicate that structural rearrangements are induced in the second and third coordination shells in samples of PaPheOH with BH4 and/or L-Phe. The 1.6 Å X-ray structure of PaPheOH shows a catalytic core that is composed of helices and strands in a bowl-like arrangement. The iron is octahedrally coordinated, by two water molecules and the evolutionary conserved His121, His126 and Glu166 that coordinates the iron with bidentate geometry. The pterin binding loop of PaPheOH (residue 81-86) adopts a conformation that is displaced by 5-6 Å from the expected pterin binding site. Consistent with the unfavourable position of the pterin binding loop is the observation that PaPheOH has a low specific activity compared to the enzymes from human and Chromobacterium violaceum. The second part of this thesis focus on the crystallization and structure determination of the actin binding domain of a-actinin (ABD). a-Actinin is located in the Z-disc of skeletal muscle were it crosslinks actin filaments to the filamentous protein titin. The ABD domain of a-actinin crystallizes in space group P21 with four molecules in the asymmetric unit. The structure of the ABD domain has been solved to a d-spacing of 2.0 Å. The two CH-domains of ABD is composed of 5 a-helices each. The a-helices fold into a closed compact conformation with extensive intramolecular contacts between the two domains. Biochemistry PaPheOH PheOH PAH phhA phenylalanine hydroxylase protein crystallography a-actinin microcrystal ABD CH-domain Biokemi Biochemistry Biokemi

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