Diem HaMai scite author profile

Exposure to excessive levels of manganese, an essential trace element, can evoke severe psychiatric and extrapyramidal motor dysfunction closely resembling Parkinson's disease. The clinical manifestations of manganese toxicity arise from focal injury to the basal ganglia. This region, characterized by intense consumption of oxygen and significant dopamine content, can incur mitochondrial dysfunction, depletion of levels of peroxidase and catalase, and catecholamine biochemical imbalances following manganese exposure. The site specificity of the pathology and the nature of the cellular damage caused by manganese have been attributed to its capacity to produce cytotoxic levels of free radicals. However, support for such a pro-oxidant role for manganese has been largely limited to inferences drawn from histopathological observations. More recently, research efforts into the molecular details of manganese toxicity have provided evidence of an etiological relationship between oxidative stress and manganese-related neurodegeneration. This review focuses on studies that evaluate the redox chemistry of manganese during the neurodegenerative process and its molecular consequences.

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Modulation of oxidative events by multivalent manganese complexes in brain tissue

HaMai

Campbell

Bondy

2001

Free Radical Biology and Medicine

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Abstract-Manganese toxicity can evoke neuropsychiatric and neuromotor symptoms, which have frequently been attributed to profound oxidative stress in the dopaminergic system. However, the characterization of manganese as a pro-oxidant remains controversial because antioxidant properties also have been associated with this metal. The current study was designed to address these disparate findings concerning the oxidative properties of manganese. The apparent ability of manganese in its divalent form to promote formation of reactive oxygen species (ROS) within a cortical mitochondrial-synaptosomal (P2) fraction was completely abolished by the addition of one five hundredth of its molarity of desferroxamine (DFO), a trivalent metal chelator. This large ratio and the high specificity of DFO for trivalent metal ions discounted the possibility of inhibition of ROS generation by direct sequestration of divalent manganese, and implied the trace presence of a trivalent metal. Further analysis suggested that this trace metal was manganic rather than ferric ion. Ferric ion was able to dampen the reactive oxygen species-generating capacity of manganous chloride, whereas manganic ion markedly promoted this property attributed to manganous ion. Such findings of the potent effects of trace amounts of trivalent cations upon Mn 2ϩ -related free radical generation offer resolution of earlier disparate findings concerning the oxidative character of manganese.

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Differential Toxicity of Aluminum Salts in Human Cell Lines of Neural Origin: Implications for Neurodegeneration

Campbell

HaMai

Bondy

2001

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Pro- or anti-oxidant manganese: a suggested mechanism for reconciliation

HaMai

Bondy

2004

Neurochemistry International

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Importance of Considering the Framework Principles in Risk Assessment for Metals

Menzie

Ziccardi²,

Lowney³

et al. 2009

Environ. Sci. Technol.

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The chemical diversity of metals and metalloids, with radically different toxicities even across oxidation states, means that assessment of risk to humans or ecological receptors can involve complex considerations. A recent “Framework” to draw together commonalities in metal/metalloid toxicity outlines generalized considerations. In this Viewpoint, Menzie et al., using exemplary species, explain their approach to aid regulation of metals in the environment in this new framing.

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Decreased expression of inflammation-related genes following inhalation exposure to manganese

et al. 2006

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Excessive exposure to manganese (Mn) by inhalation can induce psychosis and Parkinsonism. The clinical manifestations of Mn neurotoxicity have been related to numerous physiological and cellular processes, most notably dopamine depletion. However, few studies have explored the molecular events that are triggered in response to exposure to Mn by inhalation. In this current study, the transcriptional patterns of genes related to oxidative stress or inflammation were examined in the brain rats of exposed to inhaled Mn during either gestation or early adulthood. The expression of genes encoding for proteins critical to an inflammatory response and/or possessing pro-oxidant properties, including TGFb and nNOS, were slightly depressed by prenatal exposure, whereas inhalation exposure to Mn during adulthood markedly down-regulated their transcription. However, when exposures to manganese occurred during gestation, the extent of altered gene expression induced by subsequent exposure to Mn in adulthood was reduced. This suggests that prior exposure to Mn may have attenuated the effects of inhalation exposure to Mn in adulthood, in which the expression of inflammation-related genes were suppressed. #

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The Chemistry of Transition Metals in Relation to Their Potential Role in Neurodegenerative Processes

HaMai

Bondy²,

Becaria³

et al. 2001

CTMC

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Cells rely on several transition metals to regulate a wide range of metabolic and signaling functions. The diversity and efficiency of their physiological functions are derived from atomic properties that are specific to transition metals, most notably an incomplete inner valence subshell. These properties impart upon these elements the ability to fluctuate among a variety of positively charged ionic forms, and a chemical flexibility that allows them to impose conformational changes upon the proteins to which they bind. By this means, transition metals can serve as the catalytic centers of enzymes for redox reactions including molecular oxygen and endogenous peroxides. This review addresses the consequences of the aberrant translocation of the redox-capable essential transition elements, iron, copper, and manganese, upon the brain with an emphasis on uncontrolled and deleterious oxidative events. The potential of metal-protein interactions in facilitating such events, and their association with the physiologically redox-inert metals zinc and aluminum, are related to their postulated contribution to the pathology of neurodegeneration.

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Setting impurity limits for endogenous substances: Recommendations for a harmonized procedure and an example using fatty acids

Jolly

Bandara

Bercu

et al. 2022

Regulatory Toxicology and Pharmacology

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Diem HaMai

Oxidative Basis of Manganese Neurotoxicity

Modulation of oxidative events by multivalent manganese complexes in brain tissue

Differential Toxicity of Aluminum Salts in Human Cell Lines of Neural Origin: Implications for Neurodegeneration

Pro- or anti-oxidant manganese: a suggested mechanism for reconciliation

Importance of Considering the Framework Principles in Risk Assessment for Metals

Decreased expression of inflammation-related genes following inhalation exposure to manganese

The Chemistry of Transition Metals in Relation to Their Potential Role in Neurodegenerative Processes

Setting impurity limits for endogenous substances: Recommendations for a harmonized procedure and an example using fatty acids

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