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Trophic Deprivation (trophic + deprivation)

Distribution by Scientific Domains

Life Sciences	100%

Selected Abstracts

Dipyridamole protects cultured rat embryonic cortical neurons from neurotoxic insult

JOURNAL OF NEUROCHEMISTRY, Issue 2002
A. D. Blake
The effects of a clinically useful cardiovascular agent, dipyridamole, were examined in a rodent tissue culture model of neural protection. Dipyridamole effectively protected rat embryonic day 18 (E18) cortical neurons from either trophic deprivation or endogenous glutathione depletion by l -buthionine (R,S) sulfoximine (BSO). Trophic deprivation was associated with an increase in intracellular oxidative stress, as determined by the increased fluorescence of dichloro, dihydrofluorescein (H2DCFDA). Dipyridamole's neural protection was time and concentration-dependent (EC50 = 342 nm), and its continuous presence in the culture medium was required. Dipyridamole or exogenously added glutathione markedly decreased trophic deprivation induced H2DCFDA fluorescence, indicating a reduction in neuronal oxidative stress. These results demonstrate that dipyridamole protects primary neuronal cultures against either trophic or chemically mediated insults, and suggest that dipyridamole has a potent antioxidant ability that compensates for glutathione depletion in primary neuronal cells. [source]

Serum or target deprivation-induced neuronal death causes oxidative neuronal accumulation of Zn2+ and loss of NAD+

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 6 2010
Christian T. Sheline
Abstract Trophic deprivation-mediated neuronal death is important during development, after acute brain or nerve trauma, and in neurodegeneration. Serum deprivation (SD) approximates trophic deprivation in vitro, and an in vivo model is provided by neuronal death in the mouse dorsal lateral geniculate nucleus (LGNd) after ablation of the visual cortex (VCA). Oxidant-induced intracellular Zn2+ release ([Zn2+]i) from metallothionein-3 (MT-III), mitochondria or ,protein Zn2+', was implicated in trophic deprivation neurotoxicity. We have previously shown that neurotoxicity of extracellular Zn2+ required entry, increased [Zn2+]i, and reduction of NAD+ and ATP levels causing inhibition of glycolysis and cellular metabolism. Exogenous NAD+ and sirtuin inhibition attenuated Zn2+ neurotoxicity. Here we show that: (1) Zn2+ is released intracellularly after oxidant and SD injuries, and that sensitivity to these injuries is proportional to neuronal Zn2+ content; (2) NAD+ loss is involved , restoration of NAD+ using exogenous NAD+, pyruvate or nicotinamide attenuated these injuries, and potentiation of NAD+ loss potentiated injury; (3) neurons from genetically modified mouse strains which reduce intracellular Zn2+ content (MT-III knockout), reduce NAD+ catabolism (PARP-1 knockout) or increase expression of an NAD+ synthetic enzyme (Wlds) each had attenuated SD and oxidant neurotoxicities; (4) sirtuin inhibitors attenuated and sirtuin activators potentiated these neurotoxicities; (5) visual cortex ablation (VCA) induces Zn2+ staining and death only in ipsilateral LGNd neurons, and a 1 mg/kg Zn2+ diet attenuated injury; and finally (6) NAD+ synthesis and levels are involved given that LGNd neuronal death after VCA was dramatically reduced in Wlds animals, and by intraperitoneal pyr vate or nicotinamide. Zn2+ toxicity is involved in serum and trophic deprivation-induced neuronal death. [source]