Unlocking the Therapeutic
Potential: Sitagliptin’s
Multifaceted Approach in Drug-Resistant Epilepsy through a Novel Mechanism
Inhibiting Protein Kinase C‑γ and a Long-Term Potentiation
Pathway
Drug-resistant epilepsy is a prominent challenge in chronic
neurological
disorders. Valproate, commonly used to treat epilepsy, can fail due
to various side effects and interactions, necessitating the exploration
of alternative treatments. Our study primarily investigated sitagliptin’s
potential as a therapeutic agent for drug-resistant epilepsy. Employing
computational modeling and enzyme assay testing, three lead compounds,
emixustat, sitagliptin, and distigmine bromide, were evaluated against
the target enzyme protein kinase C-γ. In vivo, experiments on a pentylenetetrazolium-induced lamotrigine-resistant
epilepsy model were conducted to test sitagliptin’s antiseizure
effects, compared with the standard phenobarbital treatment. Emixustat
and sitagliptin showcased strong inhibitory properties, while distigmine
bromide was less effective in the enzyme assay. Mechanistic insights
revealed sitagliptin’s ability to modulate the seizure grade
and first myoclonic jerk latency via oxidative stress markers, like
reduced glutathione and glutathione peroxidase emphasizing its antioxidative
role in epilepsy. Additionally, it demonstrated anti-inflammatory
effects by significantly reducing proinflammatory markers interleukin-1β
and interleukin-6. The modulation of key genes of the long-term potentiation
pathway, particularly protein kinase C-γ and metabotropic glutamate
receptor 5, was evident through mRNA expression levels. Finally, sitagliptin
showed potential neuroprotective properties, limiting pentylenetetrazolium-induced
neuronal loss in the hippocampal region. Collectively, our findings
suggest sitagliptin’s multidimensional therapeutic potential
for drug-resistant epilepsy specifically via a long-term potentiation
pathway by inhibiting protein kinase C-γ.