Manganese transport via the transferrin mechanism.

Excessive manganese (Mn) uptake by brain cells, particularly in regions like the basal ganglia, can lead to toxicity. Mn(2+) is transported into cells via a number of mechanisms, while Mn(3+) is believed to be transported similarly to iron (Fe) via the transferrin (Tf) mechanism. Cellular Mn uptake is therefore determined by the activity of the mechanisms transporting Mn into each type of cell and by the amounts of Mn(2+), Mn(3+) and their complexes to which these cells are exposed; this complicates understanding the contributions of each transporter to Mn toxicity.

An analysis of the effects of Mn2+ on oxidative phosphorylation in liver, brain, and heart mitochondria using state 3 oxidation rate assays.

Manganese (Mn) toxicity is partially mediated by reduced ATP production. We have used oxidation rate assays--a measure of ATP production--under rapid phosphorylation conditions to explore sites of Mn(2+) inhibition of ATP production in isolated liver, brain, and heart mitochondria. This approach has several advantages.

Nanoparticle (NP) uptake by type I alveolar epithelial cells and their oxidant stress response.

Mammalian cells take up nanoparticles (NPs) and some NPs increase ROS. We use imaging and measure ROS in parallel to evaluate NP-cell interactions with type I-like alveolar epithelial cells exposed to NPs at 1.2 µg/cm(2) .

Speciation of manganese in cells and mitochondria: a search for the proximal cause of manganese neurotoxicity.

Recent studies of speciation of manganese (Mn) in brain mitochondria, neuron-like cells, and astrocytes are reviewed. No evidence is found for oxidation of Mn(2+) complexes to a Mn(3+) complex. The only evidence for any Mn(3+) complex is found in a spectrum essentially identical to that of mitochondrial manganese superoxide dismutase (MnSOD).

Determining the oxidation states of manganese in NT2 cells and cultured astrocytes.

Excessive brain manganese (Mn) can produce a syndrome called "manganism", which correlates with loss of striatal dopamine and cell death in the striatum and globus pallidus. The prevalent hypothesis for the cause of this syndrome has been oxidation of cell components by the strong oxidizing agent, Mn(3+), either formed by oxidation of intracellular Mn(2+) or transported into the cell as Mn(3+). We have recently used X-ray absorption near edge structure spectroscopy (XANES) to determine the oxidation states of manganese complexes in brain and liver mitochondria and in nerve growth factor (NGF)-induced and non-induced PC12 cells.

Bcl-2 sensitive mitochondrial potassium accumulation and swelling in apoptosis.

During etoposide-induced apoptosis in HL-60 cells, cytochrome c release was associated with mitochondrial swelling caused by increased mitochondrial potassium uptake. The mitochondrial permeability transition was also observed; however, it was not the primary cause of mitochondrial swelling. Potassium uptake and swelling of mitochondria were blocked by bcl-2 overexpression.

Determining the oxidation states of manganese in PC12 and nerve growth factor-induced PC12 cells.

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+.

Calcium and mitochondria.

The literature suggests that the physiological functions for which mitochondria sequester Ca(2+) are (1). to stimulate and control the rate of oxidative phosphorylation, (2). to induce the mitochondrial permeability transition (MPT) and perhaps apoptotic cell death, and (3).

Determination of the oxidation states of manganese in brain, liver, and heart mitochondria.

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.

Bcl-2 prevents abnormal mitochondrial proliferation during etoposide-induced apoptosis.

At the late stage of etoposide-induced apoptosis in HL-60 cells, marked by condensation of chromatin, mitochondria increase in numbers. There is also a drastic increase in mitochondrial DNA content. This increase in mitochondrial numbers and DNA content is an indicator of mitochondrial proliferation during apoptosis.

Bcl-2 and tBid proteins counter-regulate mitochondrial potassium transport.

The mechanism of cytochrome c release from mitochondria in apoptosis remains obscure, although it is known to be regulated by bcl-2 family proteins. Here we describe a set of novel apoptotic phenomena--stimulation of the mitochondrial potassium uptake preceding cytochrome c release and regulation of such potassium uptake by bcl-2 family proteins. As a result of increased potassium uptake, mitochondria undergo moderate swelling sufficient to release cytochrome c.

XANES spectroscopy: a promising tool for toxicology: a tutorial.

X-ray absorption near edge structure (XANES) spectroscopy can provide information on the oxidation state of metal ions within a biological sample and also the complexes in which it is found. This type of information could be of great use to toxicologists in understanding the mechanism of action of many toxic agents. The prospect of using a sophisticated physical technique such as XANES may be somewhat intimidating for those without a strong physical background.

Growth plate chondrocyte maturation is regulated by basal intracellular calcium.

Among the cellular events that are associated with the process of endochondral ossification is an incremental increase in chondrocyte basal intracellular free Ca(2+) concentration ([Ca(2+)](i)) from 50 to 100 nM. To determine if this rise in [Ca(2+)](i) functionally participates in the maturational process of growth plate chondrocytes (GPCs), we examined its effect on several markers of hypertrophy, including annexin V, bone morphogenetic protein-6, type X collagen, and indian hedgehog. Expression of these genes was determined under conditions either where the Ca(2+) chelator EGTA was used to deplete extracellular Ca(2+) and lower [Ca(2+)](i) to < 50 nM or where the extracellular addition of 5 mM CaCl(2) was used to elevate [Ca(2+)](i) to > 100 nM.