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Regulation of tyrosine hydroxylase by protein phosphatase 2ASaraf, Amit. Strack, Stefan. January 2008 (has links)
Thesis supervisor: Stefan Strack. Includes bibliographic references (p. 77-88).
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Study of several aspects of the enzyme tyrosine hydroxylaseGibson, Sheila M. January 1968 (has links)
Interest in brain catecholamines has grown considerably in the last few years in view of their possible role as neurotransmitters.
This investigation deals primarily with the enzyme tyrosine hydroxylase which is thought to be the rate limiting step in catecholamine synthesis.
Using tyrosine hydroxylase measurements and catecholamine
depletion techniques,attempts were made to determine the site of increased synthesis of catecholamines in animals exposed to cold. Brain, heart and spleen do not appear to be the organs involved in this change. Adrenals may be of significance but the results were suggestive rather than conclusive.
Tyrosine hydroxylase distribution in brain was determined in various regions of rat, rabbit and cat brain, and activity was shown to be highest in the caudate, septal area, nucleus accombens, and anterior perforating substance, with much lower activities in other regions such as hippocampus, amygdala, hypothalamus, thalamus, cortex, cerebellum and brain stem.
Using these distribution studies as indications of normal tyrosine hydroxylase activity in areas of rat brain, and electrolytic lesion techniques, studies were carried out to determine noradrenergic and dopanergic pathways in brain. Catecholamine fibers from their origin in the midbrain were traced in the midbrain and diencephalon to the caudate and septal area, and the relative positions of each group of fibers determined along their course. / Medicine, Faculty of / Graduate
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Establishment of a Parkinson¡¦s disease model in zebrafishFeng, Chien-Wei 01 September 2011 (has links)
Recently, the zebrafish has been considered an important animal model that can be used to investigate human diseases and drug development. Parkinson¡¦s disease (PD), an
important neurodegenerative disorder, is characterized by the progressive loss of dopaminergic (DA) neurons in the substantia nigra and movement defects, including bradykinesia, tremor, and postural imbalance. However, current treatments for PD are limited and mainly improve only the clinical symptoms of the disease. Thus, a neurodegenerative rat model has been widely used for a long while to search for a new treatment for PD. However, the use of rats as an animal model has certain limitations such as breeding, efficiency, and high dosage. Recently, researchers indicated that neurotoxins such as rotenone, 6-hydroxydopamine (6-OHDA), and paraquat can induce Parkinson¡¦s-like symptoms in zebrafish, and this may be a useful PD model because of the complete development of the zebrafish nervous system, low costs, and low dosage. In this study, we treated zebrafish with 6-OHDA and analyzed their locomotor activity to establish an in vivo animal model of PD. Then, we analyzed the mRNA expression of parkin and PINK1 by reverse transcription¡Vpolymerase chain reaction (RT-PCR).Moreover, we observed tyrosine hydroxylase (TH) expression by immunohistochemical (IHC) staining to confirm if this can be used as a PD model. Finally, we found that
treatment with 6-OHDA significantly reduced TH expression. We observed a similar declining trend in the case of mammals. Likewise, parkin and PINK1 mRNA expressions were also decreased after treatment with 6-OHDA. In summary, our study provides a feasible in vivo Parkinson¡¦s model, and a small volume of drugs or compounds can be screened using this model.
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Studies of the chemical and regulatory mechanisms of tyrosine hydroxylaseFrantom, Patrick Allen 16 August 2006 (has links)
Tyrosine hydroxylase (TyrH) catalyzes the pterin-dependent hydroxylation of
tyrosine to form dihydroxyphenylalanine. The enzyme requires one atom of ferrous iron
for activity. Using deuterated 4-methylphenylalanine substrates, intrinsic primary and
secondary isotope effects of 9.6 ± 0.9 and 1.21 ± 0.08 have been determined for benzylic
hydroxylation catalyzed by TyrH. The large, normal secondary isotope effect is
consistent with a mechanism involving hydrogen atom abstraction to generate a radical
intermediate. The similarity of the isotope effects to those measured for benzylic
hydroxylation catalyzed by cytochrome P-450 suggests that a high-valent, ferryl-oxo
species is the hydroxylating species in TyrH. Uncoupled mutant forms of TyrH have
been utilized to unmask isotope effects on steps in the aromatic hydroxylation pathway
which also implicate a ferryl-oxo intermediate. Inverse secondary isotope effects were
seen when 3,5-2H2-tyrosine was used as a substrate for several mutant enzyme forms.
This result is consistent with a direct attack by a ferryl-oxo species on the aromatic ring
of tyrosine forming a cationic intermediate. Rapid-freeze quench Mössbauer studies have provided preliminary spectroscopic evidence for an Fe(IV) intermediate in the reaction
catalyzed by TyrH.
The role of the iron atom in the regulatory mechanism has also been investigated.
The iron atom in TyrH, as isolated, is in the ferric form and must be reduced for activity.
The iron can be reduced by a number of one-electron reductants including
tetrahydrobiopterin, ascorbate, and glutathione; however, it appears that BH4 (kred = 2.8 ±
0.1 mM-1 s-1) is the most likely candidate for reducing the enzyme in vivo. A one-electron
transfer would require a pterin radical. Rapid-freeze quench EPR experiments aimed at
detecting the intermediate were unsuccessful, suggesting that it decays very rapidly by
reducing another equivalent of enzyme. The active Fe(II) form can also become oxidized
by oxygen (210 ± 30 M-1 s-1); this increases the affinity of catecholamine inhibitors.
Serine 40 can be phosphorylated to relieve the inhibition; however, results with S40E
TyrH show phosphorylation does not have an effect on the rate constant for reduction of
the enzyme but causes a 40% decrease in the rate constant of oxidation.
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Acute regulation of tyrosine hydroxylaseGordon, Sarah January 2009 (has links)
Research Doctorate - Doctor of Philosopy (PhD) / Tyrosine hydroxylase (TH), the rate-limiting enzyme in catecholamine biosynthesis, is regulated acutely by a combination of phosphorylation of three key serine (Ser) residues (Ser19, Ser31 and Ser40), and feedback inhibition by the catecholamines. Phosphorylation of Ser40 directly increases TH activity by relieving feedback inhibition of the enzyme. The phosphorylation of Ser19 or Ser31 can potentiate the phosphorylation of Ser40 in a process known as hierarchical phosphorylation. The 2 major human TH isoforms, hTH1 and hTH2, are differentially regulated by hierarchical phosphorylation in vitro. In this study, the human neuroblastoma SH-SY5Y cell line has been transfected with hTH1 and hTH2, and it has been demonstrated that phosphorylation of Ser31 potentiates the phosphorylation of Ser40 in hTH1. Phosphorylation of the equivalent Ser31 residue in hTH2 was not detectable, and thus this enzyme is not subject to Ser31-mediated hierarchical phosphorylation of Ser40 in situ. This is the first study to demonstrate that hTH1 and hTH2 are differentially regulated in situ. In addition, we have examined the nature of feedback inhibition of TH by the catecholamines. In addition to the high affinity, non-dissociable dopamine binding that is relieved by Ser40 phosphorylation, we have identified a second low affinity, readily dissociable binding site which regulates TH activity both in vitro and in situ regardless of the phosphorylation state of the enzyme. This low affinity binding site responds to changes in cytosolic catecholamine levels in situ in order to regulate TH activity. This work has contributed to our understanding of the complex nature of the regulation of TH activity.
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Functional Studies of Dopamine-D2S Receptor Signaling through the RASA3 PathwayChang, Chao January 2014 (has links)
RASA3 (Ras p21 GTPase Activating Protein 3) is required for D2SR (Dopamine D2 Short Receptor) induced ERK1/2 inhibition in pituitary lactotroph GH4ZR7 cells. We hypothesized that RASA3 may be important for D2SR signaling to inhibit ERK1/2 in dopamine neurons, and thus negatively regulate TH (Tyrosine Hydroxylase) expression and activity. We designed and made shRASA3 lentivirus and showed that it inhibits RASA3 expression. Lentivirus mediated RASA3 knockdown can partially reverse the D2SR mediated ERK1/2 inactivation in GH4ZR7 cells. We then showed that knockdown of RASA3 in dopamine-secreting PC12 cells increased NGF-stimulated ERK1/2 in cells expressing D2SR, but not in cells lacking D2SR, thus implicating RASA3 plays a role in D2SR-mediated inhibition of ERK1/2 signaling. We also found that knockdown of RASA3 increased TH protein levels in cells expressing D2R receptors but not those without D2SR, suggesting that D2SR tonically inhibits the synthesis of TH. We also found preliminary indication that mutant RASA3 mice show increased level of TH in SN compared to WT mice. RASA3 mutant mice showed no striking changes in basal locomotion, anxiety or depression phenotypes, but further studies are needed to specifically address dopamine-driven behaviors. In summary, our data support the role of RASA3 in mediating D2SR-induced inhibition of ERK1/2 in dopamine neurons to negatively regulate TH expression and activity.
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Serotonin biosynthesis and receptors in helminthsHamdan, Fadi F. January 2000 (has links)
No description available.
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Studies of the relationship of protein structure to regulation and catalysis in tyrosine hydroxylaseSura, Giri Raju 17 September 2007 (has links)
Tyrosine hydroxylase (TyrH) catalyzes the rate-limiting step in the synthesis of the catecholamine neurotransmitters dopamine, epinephrine, and norepinephrine. Phosphorylation of Ser40 of rat TyrH activates the enzyme by decreasing the affinity for catecholamines. In humans, there are four different TyrH isoforms with varying lengths for the regulatory domain. DOPA and dopamine binding studies were performed on the phosphorylated and unphosphorylated human isoforms. The Kd for DOPA was increased two times upon phosphorylation of hTyrH1, but no change was seen for hTyrH4; the Kd value decreased with the increase in the size of regulatory domain. The small effect on the Kd value for DOPA upon phosphorylation of hTyrH suggests that DOPA does not regulate the activity of hTyrH. Dopamine binds very tightly and upon phosphorylation the affinity for dopamine is decreased. This Kd value decreases with the increase in the length of the regulatory domain. The crystal structures of substrate complexes of the homologous enzyme phenylalanine hydroxylase (PheH) show a large movement of a surface loop (residues 131-155) upon amino acid binding. The corresponding loop residues (175-200) in TyrH play an important role in DOPA formation. This conformational change in TyrH loop was studied with fluorescence anisotropy. Three tryptophan residues in the TyrH, at positions 166, 233, and 372, were mutated to phenylalanine, and Phe184 was mutated to tryptophan. An increase in anisotropy was observed in the presence of phenylalanine and 6-methyl-5-deazatetrahydropterin (6M5DPH4), but the magnitude of the change of anisotropy with 6M5DPH4 was greater than that with phenylalanine. Further characterization of the sole tryptophan in the loop showed a decrease in the amplitude of the local motion only in the presence of 6M5DPH4 alone. The conformational change in wild type TyrH was examined by H/D exchange LC/MS spectroscopy in the presence of the natural ligands. Time-course dependent deuterium incorporation into the loop in the presence of ligands indicated that the pterin alone can induce the conformational change in the loop irrespective of whether iron is reduced or oxidized. From these results, one can conclude that the loop undergoes a conformational change upon pterin binding, making the active site better for amino acid binding.
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Autonomic Control of Cardiac FunctionSteele, Shelby L 08 February 2011 (has links)
Cardiac parasympathetic tone mediates hypoxic bradycardia in fish, however the specific cholinergic mechanisms underlying this response have not been established. In Chapter 2, bradycardia in zebrafish (Danio rerio) larvae experiencing translational knockdown of the M2 muscarinic receptor was either prevented or limited at two different levels of hypoxia (PO2 = 30 or 40 Torr). Also, M2 receptor deficient fish exposed to exogenous procaterol (a presumed β2-adrenergic receptor agonist) had lower heart rates than similarly treated control fish, implying that the β2-adrenergic receptor may have a cardioinhibitory role in this species.
Zebrafish have a single β1-adrenergic receptor (β1AR), but express two distinct β2-adrenergic receptor genes (β2aAR and β2bAR). Zebrafish β1AR deficient larvae described in Chapter 3 had lower resting heart rates than control larvae, which conforms to the stereotypical stimulatory nature of this receptor in the vertebrate heart. However, in larvae where loss of β2a/β2bAR and β1/β2bAR function was combined, heart rate was significantly increased. This confirmed my previous observation that the β2-adrenergic receptor has an inhibitory effect on heart rate in vivo.
Fish release the catecholamines epinephrine and norepinephrine (the endogenous ligands of adrenergic receptors) into the circulation when exposed to hypoxia, if sufficiently severe. Zebrafish have two genes for tyrosine hydroxylase (TH1 and TH2), the rate limiting enzyme for catecholamine synthesis, which requires molecular oxygen as a cofactor. In Chapter 4, zebrafish larvae exposed to hypoxia for 4 days exhibited increased whole body epinephrine and norepinephrine content. TH2, but not TH1, mRNA expression decreased after 2 days of hypoxic exposure.
The results of this thesis provide some of the first data on receptor-specific control of heart rate in fish under normal and hypoxic conditions. It also provides the first observations that catecholamine turnover and the mRNA expression of enzymes required for catecholamine synthesis in larvae are sensitive to hypoxia. Taken together, these data provide an interesting perspective on the balance of adrenergic and cholinergic control of heart rate in zebrafish larvae.
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Autonomic Control of Cardiac FunctionSteele, Shelby L 08 February 2011 (has links)
Cardiac parasympathetic tone mediates hypoxic bradycardia in fish, however the specific cholinergic mechanisms underlying this response have not been established. In Chapter 2, bradycardia in zebrafish (Danio rerio) larvae experiencing translational knockdown of the M2 muscarinic receptor was either prevented or limited at two different levels of hypoxia (PO2 = 30 or 40 Torr). Also, M2 receptor deficient fish exposed to exogenous procaterol (a presumed β2-adrenergic receptor agonist) had lower heart rates than similarly treated control fish, implying that the β2-adrenergic receptor may have a cardioinhibitory role in this species.
Zebrafish have a single β1-adrenergic receptor (β1AR), but express two distinct β2-adrenergic receptor genes (β2aAR and β2bAR). Zebrafish β1AR deficient larvae described in Chapter 3 had lower resting heart rates than control larvae, which conforms to the stereotypical stimulatory nature of this receptor in the vertebrate heart. However, in larvae where loss of β2a/β2bAR and β1/β2bAR function was combined, heart rate was significantly increased. This confirmed my previous observation that the β2-adrenergic receptor has an inhibitory effect on heart rate in vivo.
Fish release the catecholamines epinephrine and norepinephrine (the endogenous ligands of adrenergic receptors) into the circulation when exposed to hypoxia, if sufficiently severe. Zebrafish have two genes for tyrosine hydroxylase (TH1 and TH2), the rate limiting enzyme for catecholamine synthesis, which requires molecular oxygen as a cofactor. In Chapter 4, zebrafish larvae exposed to hypoxia for 4 days exhibited increased whole body epinephrine and norepinephrine content. TH2, but not TH1, mRNA expression decreased after 2 days of hypoxic exposure.
The results of this thesis provide some of the first data on receptor-specific control of heart rate in fish under normal and hypoxic conditions. It also provides the first observations that catecholamine turnover and the mRNA expression of enzymes required for catecholamine synthesis in larvae are sensitive to hypoxia. Taken together, these data provide an interesting perspective on the balance of adrenergic and cholinergic control of heart rate in zebrafish larvae.
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