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Query: UNIPROT:P04179 (
MnSOD
)
2,777
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
We report
Mn superoxide dismutase
(SOD) protein and activity in a patient with familial autosomal recessive Lewy body-negative
parkinsonism
in comparison with patients with sporadic Parkinson's disease (PD) and controls. We recently proved linkage of this family with markers of chromosome 6 at 6q25.2-27, which included the Mn SOD gene. We used a novel polymorphic mutation at -9 position of the signal peptide of the Mn SOD precursor protein, which caused valine to alanine substitution. All the affected members of this family showed homozygosity for alanine, whereas nonaffected members, sporadic PD patients, and the control subjects studied showed either heterozygosity of alanine and valine or homozygosity of valine. The Mn SOD activity of this familial patient was the highest among the PD patients and the control subjects studied, and an abundant expression of Mn SOD was found in the substantia nigra. The molecular weight of Mn SOD protein by Western blotting of this patient was essentially similar to that of PD patients and the control subjects. High Mn SOD activity may constitute a genetic risk factor in this familial patient. The difference in the signal peptide sequence may affect the expression of Mn SOD within mitochondria; however, it is unlikely that loss of function type Mn SOD mutation is the cause of this familial
parkinsonism
. Mn SOD in sporadic PD patients was similar to that in controls.
...
PMID:Mn SOD activity and protein in a patient with chromosome 6-linked autosomal recessive parkinsonism in comparison with Parkinson's disease and control. 937 4
This review discusses the etiology and pathogenesis of Parkinson's disease (PD). Mitochondrial respiratory failure and oxidative stress appear to be two major contributors to nigral neuronal death in PD. Complex I deficiency has been reported by several groups and appears to be one of the basic abnormalities responsible for mitochondrial failure. The principal question is whether or not complex I deficiency is primary or secondary. The second question is whether or not complex I deficiency is localized in the nigrostriatal system or is systemically present. It is our impression that complex I deficiency is not the primary cause but that its deficiency appears to be systemic. The primary cause may be the combination of genetic background and potential nigral neurotoxins. Exposure of nigral neurons to a high risk for oxidative damage because of its high dopamine content may be the reason for more pronounced nigral complex I deficiency compared to systemic organs. Oxidative stress and mitochondrial failure produce a vicious cycle in nigral neurons. To explore the genetic risk factors of sporadic PD, studies on familial PD and
parkinsonism
are important. Recently, an autosomal dominant form of familial PD was found to be caused by point mutations of the alpha-synuclein gene, and an autosomal recessive familial
parkinsonism
was mapped to the long arm of chromosome 6 near the
Mn-SOD
gene locus. Information obtained in these familial cases will contribute to the research on sporadic PD.
...
PMID:Mitochondrial dysfunction in Parkinson's disease. 974 80
Hydroxyl radical (.OH) levels in blood, superoxide dismutase (SOD) activity in plasma (plasma-SOD) and in red blood cells (RBC) relative to Cu,Zn-SOD (SOD1) protein (RBC-SOD/SOD1), SOD1 protein in RBC (SOD1/RBC) and plasma (SOD1/plasma), and
Mn-SOD
protein in plasma (SOD2/plasma) were measured in patients with Parkinson's disease (PD), multiple-system atrophy (MSA) with
parkinsonism
, and in control subjects. Patients with PD had significantly higher.OH and plasma-SOD values and significantly lower RBC-SOD/SOD1 and SOD1/RBC values than the corresponding MSA and control values. In PD, RBC-SOD/SOD1 values were significantly lower in older patients and were negatively correlated with age.OH levels were significantly higher in PD patients with early onset, a long period of illness or severe Yahr stage, and were negatively correlated with onset and positively correlated with duration of illness. RBC-SOD/SOD1 values in PD patients who received pergolide therapy were significantly higher than those in PD patients who received neither pergolide nor bromocriptine therapy. Therefore, the higher.OH level and the lower SOD1 activity may play a role in the onset and progression of PD, and pergolide may act neuroprotectively by inducing SOD1 activity.
...
PMID:Hydroxyl radical and superoxide dismutase in blood of patients with Parkinson's disease: relationship to clinical data. 1056 21
Excess brain manganese can produce toxicity with symptoms that resemble those of
Parkinsonism
and causes that remain elusive. Manganese accumulates in mitochondria, a major source of superoxide, which can oxidize Mn2+ to the powerful oxidizing agent Mn3+. Oxidation of important cell components by Mn3+ has been suggested as a cause of the toxic effects of manganese. Determining the oxidation states of intramitochondrial manganese could help to identify the dominant mechanism of manganese toxicity. Using X-ray absorbance near edge structure (XANES) spectroscopy, we have characterized the oxidation state of manganese in mitochondria isolated from brain, liver, and heart over concentrations ranging from physiological to pathological. Results showed that (i) spectra from different model manganese complexes of the same oxidation state were similar to each other and different from those of other oxidation states and that the position of the absorption edge increases with oxidation state; (ii) spectra from intramitochondrial manganese in isolated brain, heart and liver mitochondria were virtually identical; and (iii) under these conditions intramitochondrial manganese exists primarily as a combination of Mn2+ complexes. No evidence for Mn3+ was detected in samples containing more than endogenous manganese levels, even after incubation under conditions promoting reactive oxygen species (ROS) production. While the presence of Mn3+ complexes cannot be proven in the spectrum of endogenous mitochondrial manganese, the shape of this spectrum could suggest the presence of Mn3+ near the limit of detection, probably as
MnSOD
.
...
PMID:Determination of the oxidation states of manganese in brain, liver, and heart mitochondria. 1469 May 15
Excessive brain Mn can produce toxicity with symptoms resembling
parkinsonism
. This syndrome, called "manganism," correlates with loss of dopamine in the striatum and cell death in the striatum and globus pallidus. A common hypothesis is that cell damage in Mn toxicity is caused by oxidation of important cell components by Mn3+. Determination of the amount of Mn3+ present, under a range of conditions, in neuronal cells and brain mitochondria represents an important step in evaluating the "damage through oxidation by Mn3+ hypothesis." In an earlier paper we used X-ray absorption near-edge structure (XANES) spectroscopy to determine the amount of Mn2+ and Mn3+ in brain mitochondria under a range of conditions. Here we extend the study to investigate the evidence for formation of Mn3+ through oxidation of Mn2+ by ROS in PC12 cells and in PC12 cells induced with nerve growth factor (NGF) to display a phenotype more like that of neurons. Although the results suggest that very small amounts of Mn3+ might be present at low Mn levels, probably in
Mn superoxide dismutase
, Mn3+ is not stabilized by complex formation in these cells and therefore does not accumulate to detectable amounts.
...
PMID:Determining the oxidation states of manganese in PC12 and nerve growth factor-induced PC12 cells. 1596 8
Manganese (Mn) is an essential nutrient for intracellular activities; it functions as a cofactor for a variety of enzymes, including arginase, glutamine synthetase (GS), pyruvate carboxylase and
Mn superoxide dismutase
(
Mn-SOD
). Through these metalloproteins, Mn plays critically important roles in development, digestion, reproduction, antioxidant defense, energy production, immune response and regulation of neuronal activities. Mn deficiency is rare. In contrast Mn poisoning may be encountered upon overexposure to this metal. Excessive Mn tends to accumulate in the liver, pancreas, bone, kidney and brain, with the latter being the major target of Mn intoxication. Hepatic cirrhosis, polycythemia, hypermanganesemia, dystonia and
Parkinsonism
-like symptoms have been reported in patients with Mn poisoning. In recent years, Mn has come to the forefront of environmental concerns due to its neurotoxicity. Molecular mechanisms of Mn toxicity include oxidative stress, mitochondrial dysfunction, protein misfolding, endoplasmic reticulum (ER) stress, autophagy dysregulation, apoptosis, and disruption of other metal homeostasis. The mechanisms of Mn homeostasis are not fully understood. Here, we will address recent progress in Mn absorption, distribution and elimination across different tissues, as well as the intracellular regulation of Mn homeostasis in cells. We will conclude with recommendations for future research areas on Mn metabolism.
...
PMID:Manganese metabolism in humans. 2929 55
