Rationally Designed PKD1 Activator Protects Against Neurodegeneration in Pre-clinical Models of Parkinson’s Disease

Oxidative stress leads to degeneration in Parkinson’s disease (PD). The key signal transduction and regulatory networks that are involved during this degenerative process in PD are currently being investigated for novel neuro-protective strategies. We recently discovered that the activation of Protein Kinase D1 (PKD1) acts as a novel compensatory mechanism in PD models and positive modulation of PKD1 can be a therapeutic strategy. Therefore, the purpose of the present study was to take a translational approach by developing a PKD1 activator and characterizing the protective function in pre-clinical models of PD. Positive genetic modulation of PKD1 by overexpression of constitutively active PKD1 protected against MPP ⁺ induced dopaminergic neurotoxicity. Pharmacological activation by Rosiglitazone protected, whereas inhibition by kb NB 142-70 exacerbated against MPP ⁺ and 6-OHDA toxicity in cell culture PD models. Importantly, peptides were rationally designed and screened for their ability to activate PKD1 using our screening methods. Peptide AK-P4 was identified to activate PKD1 specifically and protect against MPP ⁺ and 6-OHDA in both N27 cells and primary mesencephalic neurons. Further AK-P4 tagged with TAT sequence (AK-P4T) delivered using intra-venous injections activated PKD1 in mice. The neuro-protective effects of AK-P4T were tested using the sub-chronic MPTP mice model. Co-treatment with AK-P4T significantly restored the neurotransmitter levels and the behavioral and locomotory activities of the MPTP mouse model of PD. Collectively, our results demonstrate that rationally designed PKD1 activator peptide AK-P4T positively modulated PKD1 and protected against neurodegeneration in the pre-clinical models of PD. Our results suggest that positive modulation of the PKD1 using AK-P4T shows promise as a potential therapeutic agent against PD.