CTR1 (Copper Transporter 1), PrPC (Cellular Prion Protein), NRAMP2 (Natural Resistance - Associated Macrophage Protein 2) and ATP7A proteins control the cell absorption and efflux of copper (Cu) ions in nervous tissues upon physiological conditions. Little is known about their regulation under reduced Cu availability, a condition underlying the onset of diffused neurodegenerative disorders. In the current study, rat neuron-like cells were exposed to Cu starvation for 48 h. The activation of Caspase-3 enzymes and the impairment of Cu,Zn Superoxide Dismutase (Cu,Zn SOD) activity depicted the initiation of a pro-apoptotic program, preliminary to the appearance of the morphological signs of apoptosis. The transcriptional response related to Cu transport proteins has been investigated. Notably, PrPC transcript and protein levels were consistently elevated upon Cu deficiency. The CTR1 protein amount was stable, despite a two-fold increase in the transcript amount, meaning the activation of post-translational regulatory mechanisms. NRAMP2 and ATP7A expression was unvaried. The up-regulated PrPC has been demonstrated to enhance the cell Cu uptake ability by about 50% with respect to the basal transport, and so sustain the Cu delivery to the Cu,Zn SOD cuproenzymes. Conclusively, the study suggests a pivotal role for PrPC in the cell adaptation to Cu limitation through a direct activity of ion uptake. In this view, the PrPC accumulation observed in several cancer cell lines could be interpreted as a molecular marker of cell Cu deficiency and a potential target of therapeutic interventions against disorders caused by metal imbalances.
Role of the Cellular Prion Protein in the neuron adaptation strategy to copper deficiency
URSO, EMANUELA;MANNO, Daniela Erminia;SERRA, Antonio;RIZZELLO, Antonia;DANIELI, Antonio;ACIERNO, Raffaele;MAFFIA, Michele
2012-01-01
Abstract
CTR1 (Copper Transporter 1), PrPC (Cellular Prion Protein), NRAMP2 (Natural Resistance - Associated Macrophage Protein 2) and ATP7A proteins control the cell absorption and efflux of copper (Cu) ions in nervous tissues upon physiological conditions. Little is known about their regulation under reduced Cu availability, a condition underlying the onset of diffused neurodegenerative disorders. In the current study, rat neuron-like cells were exposed to Cu starvation for 48 h. The activation of Caspase-3 enzymes and the impairment of Cu,Zn Superoxide Dismutase (Cu,Zn SOD) activity depicted the initiation of a pro-apoptotic program, preliminary to the appearance of the morphological signs of apoptosis. The transcriptional response related to Cu transport proteins has been investigated. Notably, PrPC transcript and protein levels were consistently elevated upon Cu deficiency. The CTR1 protein amount was stable, despite a two-fold increase in the transcript amount, meaning the activation of post-translational regulatory mechanisms. NRAMP2 and ATP7A expression was unvaried. The up-regulated PrPC has been demonstrated to enhance the cell Cu uptake ability by about 50% with respect to the basal transport, and so sustain the Cu delivery to the Cu,Zn SOD cuproenzymes. Conclusively, the study suggests a pivotal role for PrPC in the cell adaptation to Cu limitation through a direct activity of ion uptake. In this view, the PrPC accumulation observed in several cancer cell lines could be interpreted as a molecular marker of cell Cu deficiency and a potential target of therapeutic interventions against disorders caused by metal imbalances.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.