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  • Hypoxia controls iron metabolism and glutamate secretion in retinal pigmented epithelial cells.

Hypoxia controls iron metabolism and glutamate secretion in retinal pigmented epithelial cells.

Biochimica et biophysica acta (2014-06-28)
Jill Harned, Steven Nagar, M Christine McGahan
ABSTRACT

Blood-barrier systems are essential in controlling iron levels in organs such as the brain and eye, both of which experience hypoxia in pathological conditions. While hypoxia's effects on numerous iron regulatory and storage proteins have been studied, little is known about how hypoxia affects iron metabolism. Iron also controls glutamate production and secretion; therefore the effects of hypoxia on iron metabolism and glutamate secretion were studied in polarized retinal pigmented epithelial (RPE) cells. Primary canine RPE were cultured in Millicells to create polarized cell cultures. Iron uptake and efflux were measured in hypoxic and normoxic conditions. RPE were loaded with ⁵⁹Fe-transferrin. Glutamate concentrations in the cell conditioned media were also measured. Hypoxia induced a large increase in iron efflux from RPE in the basolateral direction. Glutamate secretion occurred mainly in the basolateral direction which is away from the retina and out of the eye in vivo. Glutamate secretion was doubled under hypoxic conditions. Hypoxia is known to induce oxidative damage. The current results show that iron, a key catalyst of free radical generation, is removed from RPE under hypoxic conditions which may help protect RPE from oxidative stress. Results obtained here indicate the importance of using polarized tight junctional cells as more physiologically relevant models for blood-barrier-like systems. While the effects of hypoxia on iron efflux and glutamate secretion may be protective for RPE cells and retina, increased glutamate secretion in the brain could cause some of the damaging neurological effects seen in stroke.

MATERIALS
Product Number
Brand
Product Description

Sigma-Aldrich
Iron, puriss. p.a., carbonyl-Iron powder, low in magnesium and manganese compounds, ≥99.5% (RT)
Iron, IRMM®, certified reference material, 0.5 mm wire
Sigma-Aldrich
Iron, foil, thickness 0.1 mm, ≥99.9% trace metals basis
Sigma-Aldrich
Iron, powder, −325 mesh, 97%
Sigma-Aldrich
Iron, chips, 99.98% trace metals basis
Sigma-Aldrich
L-Glutamic acid hydrochloride
Iron, foil, light tested, 25x25mm, thickness 0.05mm, hard, 99.5%
Iron, foil, 6mm disks, thickness 0.5mm, hard, 99.5%
Iron, foil, 50mm disks, thickness 0.25mm, hard, 99.5%
Iron, foil, light tested, 100x100mm, thickness 0.025mm, as rolled, 99.99+%
Iron, foil, 8mm disks, thickness 0.05mm, as rolled, 99.99+%
Iron, foil, 6mm disks, thickness 0.125mm, hard, 99.5%
Iron, foil, not light tested, 100x100mm, thickness 0.005mm, 99.85%
Iron, foil, 50mm disks, thickness 0.38mm, hard, 99.5%
Iron, foil, light tested, 25x25mm, thickness 0.075mm, hard, 99.5%
Iron, foil, 6mm disks, thickness 0.020mm, 99.85%
Iron, foil, light tested, 100x100mm, thickness 0.025mm, hard, 99.5%
Iron, foil, 6mm disks, thickness 0.125mm, as rolled, 99.99+%
Iron, foil, 8mm disks, thickness 0.05mm, hard, 99.5%
Iron, foil, not light tested, 100x100mm, thickness 0.007mm, 99.85%
Iron, foil, 6mm disks, thickness 0.007mm, 99.85%
Iron, foil, 50mm disks, thickness 0.5mm, hard, 99.5%
Iron, foil, 8mm disks, thickness 0.020mm, 99.85%
Iron, foil, light tested, 300x300mm, thickness 0.075mm, hard, 99.5%
Iron, foil, 8mm disks, thickness 0.38mm, hard, 99.5%
Iron, foil, 8mm disks, thickness 0.003mm, 99.85%
Iron, foil, 6mm disks, thickness 0.004mm, 99.85%
Iron, foil, 50mm disks, thickness 0.1mm, hard, 99.5%
Iron, foil, light tested, 25x25mm, thickness 0.05mm, as rolled, 99.99+%
Iron, foil, light tested, 100x100mm, thickness 0.038mm, hard, 99.5%