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)

The exact molecular mechanism of progressive loss of neuromelanin containing nigrostriatal dopaminergic neurons in Parkinson's disease (PD) remains unknown, yet evidence suggests that iron might play an important role in PD pathology. In this study we have determined the neuroprotective role of coenzyme Q(10) (CoQ(10)) in ironinduced apoptosis in cultured human dopaminergic (SK-N-SH) neurons, in metallothionein gene- manipulated mice, and in alpha-synuclein knockout (alpha-synko) mice with a primary objective to assess a possible therapeutic and anti-inflammatory potential for CoQ(10) in PD. Iron-induced mitochondrial damage and apoptosis were characterized by reactive oxygen species production, increased metallothionein and glutathione synthesis, caspase- 3 activation, NF-kappaB induction, and decreased Bcl-2 expression, without any significant change in Bax expression. Lower concentrations of FeSO4 (1-10 microM) induced perinuclear aggregation of mitochondria, whereas higher concentrations (100-250 microM) induced CoQ(10) depletion, plasma membrane perforations, mitochondrial damage, and nuclear DNA condensation and fragmentation. FeSO(4)-induced deleterious changes were attenuated by pretreatment with CoQ(10) and by deferoxamine, a potent iron chelator, in SK-N-SH cells. 1-Methyl, 4-phenyl, 1,2,3,6- tetrahydropyridine (MPTP)-induced striatal release of free iron, and NF-kappaB expression were significantly increased; whereas ferritin and melanin synthesis were significantly reduced in the substantia nigra pars compacta (SNpc) of MT(dko) mice as compared with control(wt) mice, MT(trans) mice, and alpha-synko mice. CoQ(10) treatment inhibited MPTP-induced NF-kappaB induction in all of the genotypes. These data suggest that glutathione and metallothionein synthesis might be induced as an attempt to combat iron-induced oxidative stress, whereas exogenous administration of CoQ(10) or of metallothionein induction might provide CoQ(10)-mediated neuroprotection in PD.
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PMID:Coenzyme Q(10) provides neuroprotection in iron-induced apoptosis in dopaminergic neurons. 1667 53

In this study a comparative analysis of iron molecules during aging was performed in locus coeruleus (LC) and substantia nigra (SN), known targets of Parkinson's Disease (PD) and related disorders. LC and SN neurons, especially the SN pars compacta, degenerate in PD and other forms of parkinsonism. Iron and its major molecular forms, such as ferritin and neuromelanin (NM), were measured in LC and SN of normal subjects at various ages. Iron levels were lower, H-ferritin/iron ratio was higher and the iron content in NM was lower in LC than in SN. Iron deposits were abundant in SN tissue, very scarse in LC tissue and completely absent in pigmented neurons of both SN and LC. In both regions H- and L-ferritins were present only in glia. This suggests that in LC neurons iron mobilization and toxicity is lower than that in SN and is efficiently buffered by NM. Ferritins accomplish the same buffering function in glial cells.
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PMID:Neuromelanin and iron in human locus coeruleus and substantia nigra during aging: consequences for neuronal vulnerability. 1675 80

In more than 90% of patients with idiopathic Parkinson's disease (PD) hyperechogenicity of the substantia nigra (SN) can be found by transcranial sonography (TCS) as a typical, stable sign. Animal experiments provided first evidence that SN hyperechogenicity may be associated with increased tissue iron levels. Two consecutive studies revealed the same association in human brain. Postmortem brains of 60 subjects without clinical signs for Parkinson's disease during life time at different ages were scanned by ultrasound with planimetric measurement of the echogenic area of the SN. Afterwards the SN was dissected and used for histological examination and determination of iron content in all brains as well as ferritin and neuromelanin content in 40 brains. A significant positive correlation was found between the echogenic area of the SN and the concentration of iron, H- and L-ferritins. A multivariate analysis performed considering the iron content showed a significant negative correlation between echogenicity and neuromelanin content of the SN. Iron staining confirmed the biochemical findings. In PD a typical loss of neuromelanin and increase of iron is observed in this brain area. However, it is not clear yet, whether iron accumulation is a primary cause or a secondary phenomenon in the disease process. Screening of genes involved in brain iron metabolism showed a significant association of some sequence variations of the ceruloplasmin gene with PD. Others were associated with the ultrasound marker for increased iron levels in both PD patients and control subjects. As SN hyperechogenicity is typical for PD or subjects with a preclinical impairment of the nigrostriatal system, these findings indicate that TCS enables the detection of increased iron and decreased neuromelanin levels at the SN, even before the clinical manifestation of PD.
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PMID:In vivo detection of iron and neuromelanin by transcranial sonography--a new approach for early detection of substantia nigra damage. 1675 82

Histopathological, biochemical and in vivo brain imaging techniques, such as magnetic resonance imaging and transcranial sonography, revealed a consistent increase of substantia nigra (SN) iron in Parkinson's disease (PD). Increased iron deposits in the SN may have genetic and non-genetic causes. There are several rare movement disorders associated with neurodegeneration, and genetic abnormalities in iron regulation resulting in iron deposition in the brain. Non-genetic causes of increased SN iron may be the result of a disturbed or open blood-brain-barrier, local changes in the normal iron-regulatory systems, intraneuronal transportation of iron from iron-rich area into the SN and release of iron from intracellular iron storage molecules. Major iron stores are ferritin and haemosiderin in glial cells as well as neuromelanin in neurons. Age- and disease dependent overload of iron storage proteins may result in iron release upon reduction. Consequently, the low molecular weight chelatable iron complexes may trigger redox reactions leading to damage of biomolecules. Additionally, upon neurodegeneration there is strong microglial activation which can be another source of high iron concentrations in the brain.
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PMID:Potential sources of increased iron in the substantia nigra of parkinsonian patients. 1701 20

Neuroferritinopathy is a progressive potentially treatable adult-onset movement disorder caused by mutations in the ferritin light chain gene (FTL1). Features overlap with common extrapyramidal disorders: idiopathic torsion dystonia, idiopathic Parkinson's disease and Huntington's disease, but the phenotype and natural history have not been defined. We studied a genetically homogeneous group of 41 subjects with the 460InsA mutation in FTL1, documenting the presentation, clinical course, biochemistry and neuroimaging. The mean age of onset was 39.4 years (SD = 13.3, range 13-63), beginning with chorea in 50%, focal lower limb dystonia in 42.5% and parkinsonism in 7.5%. The majority reported a family history of a movement disorder often misdiagnosed as Huntington's disease. The disease progressed relentlessly, becoming generalized over a 5-10 year period, eventually leading to aphonia, dysphagia and severe motor disability with subcortical/frontal cognitive dysfunction as a late feature. A characteristic action-specific facial dystonia was common (65%), and in 63% there was asymmetry throughout the disease course. Serum ferritin levels were low in the majority of males and post-menopausal females, but within normal limits for pre-menopausal females. MR brain imaging was abnormal on all affected individuals and one presymptomatic carrier. In conclusion, isolated parkinsonism is unusual in neuroferritinopathy, and unlike Huntington's disease, cognitive changes are absent or subtle in the early stages. Depressed serum ferritin is common and provides a useful screening test in routine practice, and gradient echo brain MRI will identify all symptomatic cases.
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PMID:Clinical features and natural history of neuroferritinopathy caused by the FTL1 460InsA mutation. 1885 24

The therapeutic use of enzyme inhibitors in treatment of neurodegenerative diseases has its origin in the anti Parkinson action of the selective monoamine oxidase (MAO) B inhibitor, l-deprenyl (selegiline ), a failed anti depressant in 1975. This led to further development of MAO- A and B, catechol-O-methyltansferase and cholinestrerase inhibitors as anti Parkinson and Alzheimer drugs. One of the main reasons for the cognitive deficit in dementia of the Alzheimer' type (AD) and in dementia with Lewy bodies (DLB) is degeneration of cholinergic cortical neurones and synaptic plasticity. This led to a correlation that similar to Parkinson's Disease (PD), cholinesterase inhibitors (ChEI) may also have therapeutic activity in AD. Significant percentage of AD and DLB subjects also nigrostriatal dopaminergic, locus ceruleous noradrenergic and raphe nucleus serotoninergic neurones. The present ChEI anti AD drugs have limited symptomatic activity and devoid of neuroprotective property that is needed for disease modifying action. It is becoming clear that there are no magic bullets for neurodegenerative disorders and shut gun approach is needed either as polypharmacology or drugs with multiple activity at different target sites in the CNS. The complex pathology of AD as well as cascade of events that leads to the neurodegenerative process has led us to develop several multifunctional neuroprotective drugs with several CNS targets with possible disease modifying activity. Employing the pharamcophore of our antiparkinson drug rasagiline (Azilect, Agilect, N-propagrgyl-1R-aminoindan) we have developed a novel multifunctional neuroprotective drug, ladostigil [TV-3326 (N-propargyl-3R-aminoindan-5yl)-ethyl methylcarbamate)], with both cholinesterase-butyrylesterase (Ch-BuE) and brain selective monoamine-oxidase (MAO) AB inhibitory activities possessing the neuroprotective-neurescue propargyl moiety, as potential treatment of AD and DLB and PD with dementias. Since brain MAO and iron increase in AD, PD and ageing, that could lead to iron dependent oxidative stress neurodegeneration, we have developed another series of multifunctional drugs (M30 HLA-20 series) which are brain permeable iron chelators- brain selective MAO inhibitors and possess the propargyl neuroprotective moiety. These series of drugs have the ability of regulating and processing APP (amyloid precursor protein) and reducing Abeta peptide, since APP is a metaloprotein, with an iron responsive element 5d'UTR similar to transferring and ferritin.
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PMID:The path from anti Parkinson drug selegiline and rasagiline to multifunctional neuroprotective anti Alzheimer drugs ladostigil and m30. 1716 53

Iron released from ferritin may trigger oxidative stress leading to progressive neurodegeneration of substantia nigra resulting in Parkinson's disease (PD). Change in the structure of ferritin may allow an easier efflux of iron. We compared with the use of ELISA the structure of ferritin (concentrations of H and L ferritins) in substantia nigra (SN) in ten cases of PD, six of incidental Lewy body (ILB) cases and 20 controls. SN concentration of L ferritin in ILB (50.6+/-11.5 ng/mg) and in PD (52.5+/-26.0) was lower than in control (97.9+/-54.9). H ferritin in PD (534.2+/-223.1) was higher than in ILB (336.9+/-87.7) and control (374.8+/-169.3). The decrease of L ferritin in SN in PD and ILB may suggest that the whole process of neurodegeneration starts with a higher availability of free iron, which is released from the ferritin shell.
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PMID:ELISA reveals a difference in the structure of substantia nigra ferritin in Parkinson's disease and incidental Lewy body compared to control. 1727 95

Earlier studies suggest that low plasma uric acid level is a risk factor for Parkinson's disease (PD), and that uric acid associates with iron-binding proteins. We therefore decided to examine plasma uric acid levels and markers of peripheral iron metabolism in PD patients and healthy controls. For the study, 40 patients with PD and 29 controls underwent clinical screening, laboratory testing, and body mass index (BMI) measurement. The average consumption of different foodstuffs and dairy products was estimated. Plasma uric acid level was significantly lower in the patients than in the controls. There were no significant differences in the levels of plasma iron parameters, but plasma uric acid correlated strongly with serum ferritin both in the patient and the control group. The BMI was slightly lower in the patients compared with the controls despite equal daily calorie consumption. Plasma uric acid level is low in patients with PD, which may have implications for both the disease pathogenesis and treatment recommendations.
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PMID:Low plasma uric acid level in Parkinson's disease. 1744 3

Parkinson's disease (PD) is characterized by the death of dopaminergic neurons in the substantia nigra. This neuronal degeneration is associated with a strong microglial activation and iron accumulation in the affected brain structures. The increased iron content may result from an increased iron penetration into the brain parenchyma due to a higher expression of lactoferrin and lactoferrin receptors at the level of the blood vessels and dopaminergic neurons in the substantia nigra in PD. Iron may also accumulate in microglial cells after phagocytosis of dopaminergic neurons. These effects may be reinforced by a lack of up-regulation of the iron storage protein ferritin, as suggested by an absence of change in iron regulatory protein 1 (IRP-1) control of ferritin mRNA translation in PD. Thus, a dysregulation of the labile iron pool may participate in the degenerative process affecting dopaminergic neurons in PD.
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PMID:Altered regulation of iron transport and storage in Parkinson's disease. 1744 30

Controlling iron/oxygen chemistry in biology depends on multiple genes, regulatory messenger RNA structures, signaling pathways and protein catalysts. Ferritin synthesis is regulated by cytokines (tumor necrosis factor-alpha and interleukin-1alpha) at various levels (transcriptional, post-transcriptional, translational) during development, cellular differentiation, proliferation and inflammation. The cellular response by cytokines to infection stimulates the expression of ferritin genes. The immunological actions of ferritin include binding to T lymphocytes, suppression of the delayed-type hypersensitivity, suppression of antibody production by B lymphocytes, and decreased phagocytosis of granulocytes. Thyroid hormone, insulin and insulin growth factor-1 are involved in the regulation of ferritin at the mRNA level. Ferritin and iron homeostasis are implicated in the pathogenesis of many disorders, including diseases involved in iron acquisition, transport and storage (primary hemochromatosis) as well as in atherosclerosis, Parkinson's disease, Alzheimer disease, and restless leg syndrome. Mutations in the ferritin gene cause the hereditary hyperferritinemia-cataract syndrome and neuroferritinopathy. Hyperferritinemia is associated with inflammation, infections and malignancies, and in systemic lupus erythematosus correlates with disease activity. Some evidence points to the importance of hyperferritinemia in dermatomyositis and multiple sclerosis, but further mechanistic investigations are warranted.
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PMID:Hyperferritinemia in autoimmunity. 1830 May 83


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