Rat astrocytes accumulate extensive DNA single-strand breakage in response to agents promoting activation of NADPH oxidase. Proinflammatory stimuli, as bacterial lipopolysaccharide associated with interferon-γ, caused a rapid/robust burst of superoxide radicals, sensitive to NADPH oxidase inhibition, followed by dismutation to H2O2, the species resulting in DNA damage via a Fenton-type reaction. There was no contribution of superoxide radical/H2O2 of mitochondrial origin and there was no evidence for the formation/involvement of peroxynitrite. On the other hand, astrocytes were virtually invulnerable to the DNA-damaging effects of exogenous peroxynitrite, an agent causing DNA strand scission in other cell types, via the Ca2+-dependent mitochondrial formation of superoxide radical/H2O2. Resistance was not dependent on scavenging of peroxynitrite but, rather, on insufficient mitochondrial Ca2+ accumulation. Hence, different manipulations resulting in an increase of the mitochondrial Ca2+ pool were invariably associated with the formation of DNA-damaging levels of H2O2. In conclusion, it appears that the strategy adopted by astrocytes to avoid inflammation-dependent genotoxic events, in particular those mediated by peroxynitrite, is to prevent mitochondrial Ca2+ accumulation, critical for the formation of secondary species largely responsible for DNA damage induced by peroxynitrite.
Susceptibility of rat astrocytes to DNA strand scission induced by activation of NADPH oxidase and collateral resistance to the effects of peroxynitrite.
GUIDARELLI, ANDREA;PALOMBA, LETIZIA;FIORANI, MARA;CANTONI, ORAZIO
2008
Abstract
Rat astrocytes accumulate extensive DNA single-strand breakage in response to agents promoting activation of NADPH oxidase. Proinflammatory stimuli, as bacterial lipopolysaccharide associated with interferon-γ, caused a rapid/robust burst of superoxide radicals, sensitive to NADPH oxidase inhibition, followed by dismutation to H2O2, the species resulting in DNA damage via a Fenton-type reaction. There was no contribution of superoxide radical/H2O2 of mitochondrial origin and there was no evidence for the formation/involvement of peroxynitrite. On the other hand, astrocytes were virtually invulnerable to the DNA-damaging effects of exogenous peroxynitrite, an agent causing DNA strand scission in other cell types, via the Ca2+-dependent mitochondrial formation of superoxide radical/H2O2. Resistance was not dependent on scavenging of peroxynitrite but, rather, on insufficient mitochondrial Ca2+ accumulation. Hence, different manipulations resulting in an increase of the mitochondrial Ca2+ pool were invariably associated with the formation of DNA-damaging levels of H2O2. In conclusion, it appears that the strategy adopted by astrocytes to avoid inflammation-dependent genotoxic events, in particular those mediated by peroxynitrite, is to prevent mitochondrial Ca2+ accumulation, critical for the formation of secondary species largely responsible for DNA damage induced by peroxynitrite.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.