The effect of iron on mammalian cortical neurons in culture

Mechanisms of divalent metal toxicity in affective disorders

Metals are required for proper brain development and play an important role in a number of neurobiological functions. The divalent metal transporter 1 (DMT1) is a major metal transporter involved in the absorption and metabolism of several essential metals like iron and manganese. However, non-essential divalent metals are also transported through this transporter. Therefore, altered expression of DMT1 can modify the absorption of toxic metals and metal-induced toxicity. An accumulating body of evidence has suggested that increased metal stores in the brain are associated with elevated oxidative stress promoted by the ability of metals to catalyze redox reactions, resulting in abnormal neurobehavioral function and the progression of neurodegenerative diseases. Metal overload has also been implicated in impaired emotional behavior, although the underlying mechanisms are not well understood with limited information. The current review focuses on psychiatric dysfunction associated with imbalanced metabolism of metals that are transported by DMT1. The investigations with respect to the toxic effects of metal overload on behavior and their underlying mechanisms of toxicity could provide several new therapeutic targets to treat metal-associated affective disorders.

Effect of iron and lipid peroxidation on development of cerebellar granule cells in vitro

The aim of this study was to investigate the effect of chelated ferric ion on neuronal development in vitro using cultured cerebellar granule cells of the rat. The cells were exposed to ferric nitrilotriacetate at varying concentrations for seven or 14 days. In addition to morphological studies, protein content determination and malondialdehyde measurement were performed. The study showed that cell development, with the addition of a lower concentration of chelated ferric ion (5 microM), could be kept in a normal condition, no significant changes in protein content and malondialdehyde production being found as compared with those of the controls, while the addition of higher concentrations of chelated ferric ion (> or = 10 microM) to the cultures demonstrated an adverse effect on development of cerebellar granule cell in vitro. Determination of protein content showed that the neuronal population decreased significantly, and the neuronal loss was inversely proportional to the iron concentrations added. Malondialdehyde measurement demonstrated that the extent of lipid peroxidation reaction increased remarkably with increasing iron concentration. A very close and highly significant correlation (gamma=0.985) between changes of malondialdehyde production and protein content was observed. These results suggest that the neuronal loss in the cultures with higher concentrations of iron was due to lipid peroxidation reaction induced by the addition of iron, and that iron overload might accelerate the process of ageing and death of cerebellar granule cells in vitro.

Immunocytochemical study with an anti-transferrin binding protein serum: a marker for avian oligodendrocytes

We have investigated immunocytochemically the localization of a transferrin binding protein (TfBP) in adult CNS of avian and mammalian species using a polyclonal antibody raised against the protein purified from hen oviduct membranes (alpha OV-TfBP). TfBP has recently been shown to be HSP108. An overall strong immunoreactivity was revealed in most parts of the avian brains, especially in the white matter. The main immunoreactivity originated in small, intensely reacting cells interpreted as oligodendrocytes. The density of TfBP-labeled oligodendrocytes of the avian brains was generally proportional to the degree of myelination. There were no marked differences in TfBP-immunostaining pattern between avian species (chick, pigeon and lovebird). On the other hand, in rat, rabbit and cat brains we could not find any TfBP-immunoreactivity. Immunoelectron microscopy has further revealed that TfBP is present in the light and medium types of oligodendrocytes which are known to have high metabolic activities. TfBP reaction product was homogeneously dispersed throughout the perinuclear cytoplasm and fine processes of oligodendrocytes. The intracytoplasmic organelles such as mitochondria and Golgi apparatus were devoid of reaction product. The presence of TfBP in oligodendrocytes implies that this protein may play an important role in transferrin-mediated iron metabolism in the CNS. The complete lack of cross-reactivity between alpha OV-TfBP and mammalian tissues suggests that there is species variability in TfBP structure. We conclude that this chick TfBP antiserum will prove useful in studies of oligodendrocytes and myelination in the avian CNS.

Effect of ferric nitrilotriacetate on rostral mesencephalic cells

After murine fetal cells from the rostral mesencephalic tegmentum were isolated, prepared, and cultured; neuronal and glial cells in primary mixed cell cultures were exposed to ferric nitrilotriacetate (Fe-NTA) at varying concentrations. Studies were performed at 23 days in culture after 14 day exposure to Fe-NTA. In addition to morphologic studies, biochemical assays including specific [3H]flunitrazepam (FLU) binding, clonazepam (CLO)-displaceable [3H]-FLU binding, Ro5-4864-displaceable [3H]-FLU binding, [3H]-FLU binding, [3H]dopamine (DA) uptake, [3H]haloperidol (HAL) binding, [3H]spiperone (SP) binding, glutamine synthetase activity (GS), and protein determinations were performed. The data demonstrate that chelated ferric iron has an adverse effect on these cells. The data also demonstrate that increasing concentrations of Fe-NTA resulted in massive neuronal dropout leaving the culture population virtually all glial; however, the specific binding of [3H]HAL and [3H]SP increased. There was a concomitant decrease in both glutamine synthetase activity and overall protein content. The mechanism of enhancement in the presence of Fe-NTA of [3H]HAL and [3H]SP binding is unknown and may be unique, but may be related to the known increase in D2 receptor ligand affinity in the presence of other multivalent cations (Ca2+ and Mg2+).

Effects of phenobarbital and phenytoin on cortical glial cells in culture

Studies were undertaken to determine the effects of 7-day phenobarbital and phenytoin exposure on 14-day-old glial cell cultures of fetal murine cortex. Biochemical markers monitored were Ro5-4684-displaceable 3H-flunitrazepam binding, 3H-beta-alanine uptake, glutamine synthetase activity, and protein content. Phenobarbital concentrations were 30, 60, and 120 micrograms/ml and phenytoin concentrations 15, 30, 60 micrograms/ml. There were no discernible phase microscopic changes at any concentration of either drug. Phenobarbital produced no significant changes in the biochemical measures monitored. Exposure to phenytoin produced no biochemical changes at 15 micrograms/ml, but did produce significant changes at 30 and 60 micrograms/ml. There was an increase in Ro5-4684-displaceable 3H-flunitrazepam binding signifying increased binding or an increase in the number of binding sites and perhaps an increased population of glial cells although, the unchanged protein content suggests that the number of glial cells was not increased. There was a decrease with 30 and 60 micrograms/ml phenytoin of 3H-beta-alanine uptake suggesting interference with normal membrane transport of this compound. The latter effect may well mirror changes in GABA uptake in glial cells in the presence of phenytoin.

Effect of ferric nitrilotriacetate on predominantly cortical glial cell cultures

Cultured glial cells were exposed to ferric nitrilotriacetate (Fe-NTA) at varying concentrations. Studies of the exposed glial cells were performed at days 29 and 36 post-conceptional age (culture days 8 and 15). In addition to morphologic studies, biochemical assays including [3H]-flunitrazepam (FLU) specific binding, Ro5-4864-displaceable 3H-FLU binding, and protein determinations were performed. At day 29 post-conceptional age, significant decreases in 3H-FLU specific binding, Ro5-4864-displaceable 3H-FLU binding, and protein determinations were discernible only in the presence of 100 microM Fe-NTA. At day 36 post-conceptional age 3H-FLU specific binding was significantly decreased at 20, 60, and 100 microM Fe-NTA concentrations, while Ro5-4864-displaceable 3H-FLU binding and protein determinations were significantly reduced at 60 and 100 microM Fe-NTA concentrations. The effects of Fe-NTA exposure appear to be both concentration and duration-of-exposure related. When compared to previously reported neuronal cell culture studies utilizing 3H-FLU specific binding, Ro5-4864-displaceable 3H-FLU binding, and protein determinations, glial cells appear to be significantly more resistant to chelated iron exposure.

Effect of ferric nitrilotriacetate on predominantly cortical neuronal cell cultures

Predominately neuronal cell cultures were produced as described in previous communications. Neuronal cells were exposed to ferric nitrilotriacetate (Fe-NTA) at varying concentrations. Studies of the neuronal cells were performed at 13 and 20 days in culture. In addition to morphologic studies, biochemical assays including choline acetyltransferase (ChAT) activity, specific [3H]flunitrazepam (FLU) binding, clonazepam (CLO)-displaceable [3H]FLU binding, Ro5-4864-displaceable [3H]FLU binding, high-affinity [3H]GABA uptake, and protein determinations were performed. The data demonstrate that chelated ferric iron has an adverse effect on predominately neuronal cultures after 7 days of exposure as measured by choline acetyltransferase activity, while other measures remained unaffected; however, after 14 days of exposure all measures were significantly decreased. The effects of Fe-NTA exposure appear to be both concentration and duration-of-exposure related.

Do oligodendrocytes mediate iron regulation in the human brain?

We used immunohistochemical studies to demonstrate that transferrin (the iron mobilization protein) and ferritin (the iron storage protein) are specifically localized in oligodendrocytes in gray and white matter of the human central nervous system. In addition, iron is also localized predominantly in oligodendrocytes. Oligodendrocytes have been well established as the cells responsible for myelin production in the central nervous system. The results of this study suggest that oligodendrocytes (or a subpopulation of oligodendrocytes) might have the additional function of mediating iron mobilization and storage in the central nervous system.

Iron-induced lipid peroxidation and inhibition of dopamine synthesis in striatum synaptosomes

Crude striatum synaptosomes (P2 fraction) from Fischer 344 female rats were incubated in the presence of ADP-chelated Fe3 (0.5-50 microM) and ascorbate (250 microM). Intrasynaptosomal conversion of tyrosine to dopamine (DA) was measured by 14CO2 evolution from L-[1-14C]tyrosine in the absence of added cofactors and DOPA decarboxylase. Malondialdehyde (MDA) was measured as an index of lipid peroxidation. A concentration-dependent inhibition of DA synthesis by ADP-Fe3./ascorbate was found with 50% inhibition occurring at 2.5 microM Fe3 concentration. This was accompanied by marked accumulation of MDA. Ascorbate or ADP alone did not affect DA synthesis and ADP-Fe3 in the absence of exogenous ascorbate was effective only above 25 microM. Exogenously added MDA did not inhibit DA synthesis. Purified synaptosomes were isolated from peroxidized and control P2 actions using sucrose gradients. Membrane microviscosity of the purified synaptosomes was assessed by nitroxyl spin labels of stearic acid using electron paramagnetic resonance techniques. There was a significant increase in membrane microviscosity as a result of ADP-Fe3./ascorbate induced peroxidation. Maleimide nitroxide spin-label binding to protein sulfhydryls was significantly modified by peroxidation of striatum synaptosomes. The weakly immobilized component of the sulfhydryl spin-label (w) was drastically decreased whereas the strongly immobilized component (s) was modified less, thus leading to a marked reduction of w/s ratio. The exposure of striatum synaptosomes to the peroxidizing system resulted in a significant increase in total iron and in a 25% decrease in protein sulfhydryl content. It is concluded that iron-induced damage to the DA synthetic system is mediated by alterations of the structural properties of nerve ending membranes.

Levels and sub-cellular distribution of physiologically important metal ions in neuronal cells cultured from chick embryo cerebral cortex

Mg2+, Ca2+, Mn2+, Zn2+, and Cu content of neurons from chick embryo cortex cultivated in chemically defined serum free growth medium was determined by energy dispersive X-ray fluorescence and atomic absorption spectroscopy. The intracellular volume of cultured neurons was determined to be 2.73 microliters/mg. Intracellular Mn2+, Fe2+, Zn2+, and Cu2+ in the cultivated neurons were 100-200 times the concentrations in the growth medium: Mg2+ and Ca2+ were 0.9 and 1.7 mM respectively, around 20 fold higher than in growth medium. Mg2+, Fe2+, Cu2+ and Zn2+ concentrations in neurons were in the range of ca. 300-600 microM, approximately 2-3 times the values previously reported in glial cells; Ca2+ and Mn2+ content of the neurons were higher by 5 and 10 fold respectively compared to glial cells. In neurons, the subcellular distribution of Fe2+, Cu2+, and Mn2+ follows the rank order: cytosol greater than microsomes greater than mitochondria; for Zn2+ the distribution differs as following: cytosol greater than mitochondria greater than microsomes. Determination of the superoxide dismutase activities in the cultivated neurons indicated that the Mn2+ linked activity predominates whereas, the Cu-Zn dependent enzyme is dominant in glial cells. Enrichment of the culture medium with Mn2+ to 2.5 microM enhanced the Mn-SOD by approximately 33% but the Cu2+-Zn2+ enzyme activity was not modified. The high Mn2+ content, the capacity to accumulate Mn2+, and the predominancy of the Mn-SOD form observed in neurons is in accord with a fundamental functional role for this metal ion in this type of brain cells.

Transferrin binding by mammalian cortical cells

Predominantly neuronal (neuronal) or non-neuronal (glial) cerebral cortical cell cultures were employed to study the kinetics and changes with maturation of 125I-diferric-transferrin uptake. The diferric-transferrin association curve of neuronal cultures at 37 degrees C was nonphasic and indicated equilibrium at 90 minutes. Dissociation was completed by 70 minutes. Diferric-transferrin specific uptake (80% of total) in neuronal cells (evaluated at days 6, 9, 13, 16, and 23 in culture) increased with maturation. Scatchard transformation of the data revealed increasing Bmax from day 6 to day 16 in culture (1626 to 2740 fmoles/mg protein). However, the K uptake was statistically unchanged over time and equaled 48.7 +/- 13.9 nM (mean +/- SD). In contrast, association studies of glial cultures documented equilibrium by 45 minutes and dissociation by 40 minutes. The concentration curves for diferric-transferrin uptake in glial cells, evaluated at days 11, 15, and 18 in culture, revealed virtually identical uptake at the three ages studied, but the percent specific uptake (58%) was less than for neurons (88%). Scatchard transformation of the data revealed no statistical alteration of Bmax or K uptake from days 11 to 18 in culture. Bmax ranged from 595 to 751 fmol/mg protein; overall K uptake was 48.3 +/- 13.2 nM (mean +/- SD).