Electrophilic compounds are a newly recognized class of redox‐active neuroprotective compounds with electron deficient, electrophilic carbon centers that react with specific cysteine residues on targeted proteins via thiol (S‐)alkylation. Although plants produce a variety of physiologically active electrophilic compounds, the detailed mechanism of action of these compounds remains unknown. Catechol ring‐containing compounds have attracted attention because they become electrophilic quinones upon oxidation, although they are not themselves electrophilic. In this study, we focused on the neuroprotective effects of one such compound, carnosic acid (CA), found in the herb rosemary obtained from Rosmarinus officinalis. We found that CA activates the Keap1/Nrf2 transcriptional pathway by binding to specific Keap1 cysteine residues, thus protecting neurons from oxidative stress and excitotoxicity. In cerebrocortical cultures, CA‐biotin accumulates in non‐neuronal cells at low concentrations and in neurons at higher concentrations. We present evidence that both the neuronal and non‐neuronal distribution of CA may contribute to its neuroprotective effect. Furthermore, CA translocates into the brain, increases the level of reduced glutathione in vivo, and protects the brain against middle cerebral artery ischemia/reperfusion, suggesting that CA may represent a new type of neuroprotective electrophilic compound.
Neurotrophins such as NGF promote neuronal survival and differentiation via the cell surface TrkA neurotrophin receptor. Compounds with neurotrophic actions that are low in molecular weight and can permeate the blood-brain barrier are promising therapeutic agents against neurodegenerative diseases such as Alzheimer's disease. Carnosic acid (CA), an electrophilic compound in rosemary, activates antioxidant responsive element (ARE)-mediated transcription via activation of Nrf2. In the present study, we discovered that CA strongly promotes neurite outgrowth of PC12h cells. NGF as well as CA activated Nrf2, whereas CA and NGF-mediated neuronal differentiation was suppressed by Nrf2 knockdown. On the other hand, CA activated TrkA-downstream kinase Erk1/2 independently of Nrf2. CA-induced p62/ZIP expression in an Nrf2-dependent manner, while the CA-induced neural differentiation was suppressed by p62/ZIP knockdown. Furthermore, CA-induced ARE activation was attenuated both by p62/ZIP knockdown and a Trk signal inhibitor. These results suggest that the CA induction of p62/ZIP by Nrf2 enhances TrkA signaling which subsequently potentiates Nrf2 pathway. This is the first demonstration that activation of the Nrf2-p62/ZIP pathway by a low-molecular natural electrophilic compound plays important roles in TrkA-mediated neural differentiation and may represent the common molecular mechanism for neurotrophic activities of electrophilic compounds.
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