Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0030567 (Parkinson's disease)
63,064 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Of the five known dopamine receptors, D1A and D2 represent the major subtypes expressed in the striatum of the adult brain. Within the striatum, these two subtypes are differentially distributed in the two main neuronal populations that provide direct and indirect pathways between the striatum and the output nuclei of the basal ganglia. Movement disorders, including Parkinson disease and various dystonias, are thought to result from imbalanced activity in these pathways. Dopamine regulates movement through its differential effects on D1A receptors expressed by direct output neurons and D2 receptors expressed by indirect output neurons. To further examine the interaction of D1A and D2 neuronal pathways in the striatum, we used homologous recombination to generate mutant mice lacking functional D1A receptors (D1A-/-). D1A-/- mutants are growth retarded and die shortly after weaning age unless their diet is supplemented with hydrated food. With such treatment the mice gain weight and survive to adulthood. Neurologically, D1A-/- mice exhibit normal coordination and locomotion, although they display a significant decrease in rearing behavior. Examination of the striatum revealed changes associated with the altered phenotype of these mutants. D1A receptor binding was absent in striatal sections from D1A-/- mice. Striatal neurons normally expressing functional D1A receptors are formed and persist in adult homozygous mutants. Moreover, substance P mRNA, which is colocalized specifically in striatal neurons with D1A receptors, is expressed at a reduced level. In contrast, levels of enkephalin mRNA, which is expressed in striatal neurons with D2 receptors, are unaffected. These findings show that D1A-/- mice exhibit selective functional alterations in the striatal neurons giving rise to the direct striatal output pathway.
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PMID:Altered striatal function in a mutant mouse lacking D1A dopamine receptors. 780 78

An enzyme responsible for the oxidation of dopamine and formation of neuromelanin in brain has not been identified. Prostaglandin H synthase is prominent in brain and possesses peroxidase activity that may cooxidize dopamine to reactive dopamine quinones. This study examined the ability of purified prostaglandin H synthase to catalyze the oxidation of dopamine in vitro. Dopamine oxidation was determined by monitoring the formation of aminochrome and by examining catechol-modified residues on protein present in the reaction mixture. Aminochrome was formed from dopamine in the presence of prostaglandin H synthase, and the reaction rate was dependent on the concentration of substrate and enzyme in the reaction mixture. Both arachidonic acid and hydrogen peroxide could serve as substrates for the prostaglandin H synthase-catalyzed oxidation of dopamine. Indomethacin blocked the reaction when arachidonic acid was used as a substrate, but not when hydrogen peroxide was used. Enzymatically oxidized dopamine covalently bound to protein, as indicated by the presence of cysteinyl-dopamine residues. Binding was significantly reduced in the absence of enzyme or in the presence of antioxidants. These results suggest that the peroxidase activity of prostaglandin H synthase is responsible for catalyzing the oxidation of dopamine to reactive dopamine quinones. It is possible that prostaglandin H synthase is responsible for the oxidation of dopamine and formation of neuromelanin in vivo, which may have implications for the development of Parkinson's disease. Furthermore, drugs such as aspirin that modulate the activity of this enzyme may provide a potential therapeutic approach for the prevention of Parkinson's disease.
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PMID:Enzymatic oxidation of dopamine: the role of prostaglandin H synthase. 783 86

Since the high-affinity state of dopamine D2 receptors may be abnormal in psychomotor diseases, it is desirable to develop a radioactive agonist to label this high-affinity site for possible clinical diagnostic use. (+)PHNO is a selective D2 agonist used to treat Parkinson's disease. We prepared [3H](+)PHNO from allyl-des-propyl(+)PHNO. In binding to dopamine receptors in homogenates of canine brain striata, [3H](+)PHNO had a dissociation constant of 0.35 nM in the absence of NaCl, and 0.56 nM in the presence of NaCl. Dopamine agonists and antagonists inhibited the binding of [3H](+)PHNO at drug concentrations similar to those inhibiting other [3H]ligands at D2 receptors, but not similar to those acting at D4 receptors. Approximately 90% of the total [3H](+)PHNO binding was specific. Guanilylimidodiphosphate markedly inhibited [3H](+)PHNO binding, suggesting that [3H](+)PHNO was binding primarily to the high-affinity state of dopamine D2 receptors rather than to D3 receptors. The density of the [3H](+)PHNO binding sites was equal to that of [3H]emonapride (or [3H]YM-09151-2), both densities of which were 1.5- to 2-fold higher than that of [3H]spiperone, compatible with the idea that [3H](+)PHNO binds to monomers of D2, while [3H]spiperone binds to dimers of D2. Although [3H](+)PHNO has good selectivity and affinity for the high-affinity state of D2, the [3H]ligand was sensitive to endogenous dopamine, since washing the tissue lowered the dissociation constant. For future in vivo labelling of D2 by an agonist, therefore, it will be essential to search for a related [3H]ligand with an even lower dissociation constant.
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PMID:Dopamine receptors labelled by PHNO. 790 15

The mechanisms that lead ultimately to neuronal death in pathological ageing of the brain remain mostly unknown as in the case of Parkinson's disease where there is a progressive and selective loss of dopaminergic neurons within the substantia nigra. Dopamine-expressing PC12 cells that were neuronally differentiated by nerve growth factor treatment were chosen as a culture model in which to study some of the changes that may occur during the course of the degenerative process. They were exposed to the calcium ionophore A23187 in order to produce a sustained rise in cytoplasmic calcium, a phenomenon related to various pathological conditions. The degenerative effects of the ionophore were dose- and time-dependent. They were characterized by early fragmentation of the neurites followed ultimately by a loss in cell viability. Biochemical changes, such as a decrease in [3H]dopamine uptake and modulations of the tyrosine hydroxylase gene, were detected before macroscopic evidence of cell suffering (e.g. neurite fragmentation) could be observed. Although an ongoing degenerative process was occurring in cell somata, PC12 cells were able to recover upon ionophore withdrawal. Characteristics of apoptosis such as chromatin condensation and DNA fragmentation were detectable in a small population of dying cells. DNA fragmentation could be prevented by the endonuclease inhibitor aurintricarboxylic acid. New protein synthesis was not required, as cycloheximide failed to prevent degeneration. Taken together, these results suggest that differentiated PC12 cells react to calcium stress through a sequence of regulatory processes which appears to be independent of the apoptotic pathway.
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PMID:Morphological and molecular characterization of the response of differentiated PC12 cells to calcium stress. 791 84

Visual evoked potentials were measured on patients with Parkinson's disease and Alzheimer's disease and normal controls to assess the function of dopamine and acetylcholine in the visual system. Dopamine is a neurotransmitter known to be present in the retina of primates and is found to be severely depleted in the substantia nigra of patients with Parkinson's disease. Acetylcholine is also known to be present in the retina, visual cortex, and superior colliculus and is found to be grossly reduced in patients with Alzheimer's disease. Stimuli were designed to preferentially activate functionally separate pathways in the visual system described as magnocellular and parvocellular. The four stimuli were a diffuse flash; an achromatic, 73' check counterphasing at 6 Hz at a contrast of 30%; an achromatic 10' check counterphasing at 2 Hz at a contrast of 85%; and an isoluminant red/green grating of 4 cpd presented using an on and off cosine ramp of 200 ms. The results indicate that an acetylcholine deficit produces a delay to the flash P2 component of the visual evoked potential. No change was detected when other stimuli were used.
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PMID:Effect of dopamine and acetylcholine on the visual evoked potential. 791 38

The effects of D2 dopamine (DA) receptor antagonism or stimulation by systemic haloperidol or quinpirole, respectively, on in vivo DA synthesis in 6-hydroxydopamine (6-OHDA)-lesioned rats and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP)-treated black mice were assessed by measuring the rate of dihydroxyphenylalanine (DOPA) accumulation following acute inhibition of L-aromatic amino acid decarboxylase with NSD-1015. 6-OHDA and MPTP caused partial lesions of nigrostriatal input to the striatum. Dopamine synthetic capacity was preserved relative to the severity of nigrostriatal lesion over a broad range of DA depletions. An exponential increase in fractional DA synthesis (the ratio DOPA/DA) was observed with increasing DA depletion, suggesting an elevation of the DA synthetic capacity per surviving DA terminal. In both lesioned rats and mice, haloperidol caused a significant increase in fractional DA synthesis above that induced by the lesion alone, while quinpirole significantly depressed fractional DA synthesis. Our results provide evidence that nigrostriatal terminals acquire increased DA synthetic capacity as nigrostriatal lesions exceed 90%, but that the increase in fractional DA synthesis observed in partially lesioned animals is not due to a loss of autoreceptor function. Pharmacological strategies to stimulate DA synthesis and release in moderately advanced Parkinson's disease should be pursued.
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PMID:Regulation by D2 dopamine receptors of in vivo dopamine synthesis in striata of rats and mice with experimental parkinsonism. 792 42

Dopamine receptors are the primary targets in the treatment of schizophrenia, Parkinson's disease, and Huntington's chorea, and are discussed in this review by Philip Seeman and Hubert Van Tol. Improved therapy may be obtained by drugs that selectively target a particular subtype of dopamine receptor. Most antipsychotic drugs block D2 receptors in direct correlation to clinical potency, except clozapine, which prefers D4 receptors. D1 and D2 receptors can enhance each other's actions, possibly through subunits of the G proteins. In schizophrenia, the D2 and D3 receptor density is elevated by 10%, while the D4 receptor density is elevated by 600%. Therefore, D4 receptors may be a target for future antipsychotic drugs. While antipsychotics originally helped to discover dopamine receptors, the five cloned dopamine receptors are now facilitating the discovery of selective antipsychotic and antiparkinson drugs.
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PMID:Dopamine receptor pharmacology. 794 Sep 91

Pharmacotherapy with levodopa for Parkinson's disease provides symptomatic benefit, but fluctuations in (or loss of) response may eventually occur. Dopamine agonists are also helpful and, when taken with low doses of levodopa, often provide sustained benefit with fewer side effects; novel agonists and new methods for their administration are therefore under study. Other therapeutic strategies are being explored, including the use of type B monoamine oxidase inhibitors to reduce the metabolic breakdown of dopamine, catechol-O-methyltransferase inhibitors to retard the breakdown of levodopa, norepinephrine precursors to compensate for deficiency of this neurotransmitter, glutamate antagonists to counteract the effects of the subthalamic nucleus, and various neurotrophic factors to influence dopaminergic nigrostriatal cells. Surgical procedures involving pallidotomy are sometimes helpful. Those involving cerebral transplantation of adrenal medullary or fetal mesencephalic tissue have yielded mixed results; benefits may relate to the presence of growth factors in the transplanted tissue. The transplantation of genetically engineered cell lines will probably become the optimal transplantation procedure. The cause of Parkinson's disease may relate to oxidant stress and the generation of free radicals. It is not clear whether treatment with selegiline hydrochloride (a type B monoamine oxidase inhibitor) delays the progression of Parkinson's disease, because the drug also exerts a mild symptomatic effect. Daily treatment with vitamin E (a scavenger of free radicals) does not influence disease progression, perhaps because of limited penetration into the brain.
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PMID:Treatment of Parkinson's disease. 797 71

l-Deprenyl is a selective, irreversible monoamine oxidase (MAO) type B inhibitor. Dopamine is a relatively good MAO-B substrate in the human brain. Because Parkinson's disease is characterized by a decrease in dopaminergic neurotransmission in the basal ganglia, the selective inhibition of MAO-B should lead to diminished metabolism of dopamine in the nigrostriatal system and a significant increase in the concentration of the neurotransmitter. MAO-B inhibition explains the clinical efficacy of l-deprenyl in the treatment of Parkinson's disease and the prevention of the conversion of protoxins such as 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine, which is oxidized by MAO-B and can cause a parkinsonian syndrome, to their active neurotoxin. In addition, l-deprenyl appears to exhibit other biochemical actions that are independent of its MAO-B activity. These actions may be the basis of the neuroprotective effects of l-deprenyl and may include the inhibition of oxidative stress, an indirect influence on the polyamine binding site of the N-methyl-d-aspartate receptor and the stimulation of neurotrophic factors.
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PMID:Biochemical actions of l-deprenyl (selegiline). 799 15

We report that exposure of cultured, postmitotic chick-embryo sympathetic neurons, to physiological concentrations of dopamine (0.1-1 mM) for 24 h initiates a cellular death process characteristic of apoptosis (= programmed-cell-death, PCD). Dopamine caused marked morphological alterations, mainly axonal disintegration and severe shrinkage and condensation of cell bodies. Flow-cytometric analysis of propidium-iodide-stained cell nuclei revealed the characteristic apoptotic nuclear fragmentation: increase in nuclear granularity and emergence of a large, distinct population of nuclei with reduced DNA content (subdiploid, apoptotic peak). These alterations were similar to changes induced by nerve growth factor (NGF) deprivation, a model of sympathetic neuronal PCD. Alterations were inhibited by the anti-oxidative agent DTT. Inappropriate, dopamine-induced activation of PCD might have a role in nigral neuronal degeneration in Parkinson's disease.
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PMID:Dopamine induces apoptosis-like cell death in cultured chick sympathetic neurons--a possible novel pathogenetic mechanism in Parkinson's disease. 804 91


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