Data di Pubblicazione:
2005
Abstract:
Calcium/phospholipid-regulated protein kinase C (PKC) signalling
is known to be involved in cellular functions relevant to brain health and disease, including ion channel modulation, receptor regulation, neurotransmitter
release, synaptic plasticity, and survival. Brain aging is characterized by altered neuronal molecular cascades and interneuronal communication in response to various stimuli. In the last few years we have provided evidence
that in rodents, despite no changes in PKC isoform levels (both calcium dependent and calcium independent), the activation/translocation process of the calcium-
dependent and -independent kinases and the content of the adaptor protein RACK1 (receptor for activated C kinase-1) are deficient in physiological brain aging. Moreover, human studies have shown that PKC and its adaptor protein RACK1 are also interdependent in pathological brain aging (e.g.,
Alzheimer’s disease); in fact, calcium-dependent PKC translocation and RACK1 levels are both deficient in an area-selective manner. These data point
to the notion that, in addition to a well-described lipid environment alteration, changes in protein–protein interactions may impair the mechanisms of PKC
activation in aging. It is interesting to note that interventions to counteract the age-related functional loss also restore PKC activation and the adaptor protein
machinery expression. A better insight into the factors controlling PKC activation may be important not only to elucidate the molecular basis of signal transmission,
but also to identify new strategies to correct or even to prevent agedependent alterations in cell-to-cell communication.
is known to be involved in cellular functions relevant to brain health and disease, including ion channel modulation, receptor regulation, neurotransmitter
release, synaptic plasticity, and survival. Brain aging is characterized by altered neuronal molecular cascades and interneuronal communication in response to various stimuli. In the last few years we have provided evidence
that in rodents, despite no changes in PKC isoform levels (both calcium dependent and calcium independent), the activation/translocation process of the calcium-
dependent and -independent kinases and the content of the adaptor protein RACK1 (receptor for activated C kinase-1) are deficient in physiological brain aging. Moreover, human studies have shown that PKC and its adaptor protein RACK1 are also interdependent in pathological brain aging (e.g.,
Alzheimer’s disease); in fact, calcium-dependent PKC translocation and RACK1 levels are both deficient in an area-selective manner. These data point
to the notion that, in addition to a well-described lipid environment alteration, changes in protein–protein interactions may impair the mechanisms of PKC
activation in aging. It is interesting to note that interventions to counteract the age-related functional loss also restore PKC activation and the adaptor protein
machinery expression. A better insight into the factors controlling PKC activation may be important not only to elucidate the molecular basis of signal transmission,
but also to identify new strategies to correct or even to prevent agedependent alterations in cell-to-cell communication.
Tipologia CRIS:
1.1 Articolo in rivista
Keywords:
Protein kinase C; PKC; Aging; Brain; RACK1; Anchoring; scaffolding; Translocation; Alzheimer’s disease; Pineal transplant
Elenco autori:
Battaini, Fiorenzo; Pascale, ALESSIA ANGELA
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