Litcius/Paper detail

Pantothenate-encapsulated liposomes combined with exercise for effective inhibition of CRM1-mediated PKM2 translocation in Alzheimer's therapy

Yisheng Chen, Lei Huang, Zhiwen Luo, Dan Han, Wei Luo, Renwen Wan, Yan Li, Yunshen Ge, Weiwei Lin, Yuchun Xie, Mingming Sun, Qian Wang, Zhiwei Li, Shiyi Chen, Yi Yang, Bin Huang, Yuzhen Xu

2024Journal of Controlled Release25 citationsDOIOpen Access PDF

Abstract

Alzheimer's disease (AD) is a complex neurodegenerative condition characterized by metabolic imbalances and neuroinflammation, posing a formidable challenge in medicine due to the lack of effective treatments. Despite considerable research efforts, a cure for AD remains elusive, with current therapies primarily focused on symptom management rather than addressing the disease's underlying causes. This study initially discerned, through Mendelian randomization analysis that elevating pantothenate levels significantly contributes to the prophylaxis of Alzheimer's disease. We explore the therapeutic potential of pantothenate encapsulated in liposomes (Pan@TRF@Liposome NPs), targeting the modulation of CRM1-mediated PKM2 nuclear translocation, a critical mechanism in AD pathology. Additionally, we investigate the synergistic effects of exercise, proposing a combined approach to AD treatment. Exercise-induced metabolic alterations share significant similarities with those associated with dementia, suggesting a potential complementary effect. The Pan@TRF@Liposome NPs exhibit notable biocompatibility, showing no liver or kidney toxicity in vivo, while demonstrating stability and effectiveness in modulating CRM1-mediated PKM2 nuclear translocation, thereby reducing neuroinflammation and neuronal apoptosis. The combined treatment of exercise and Pan@TRF@Liposome NP administration in an AD animal model leads to improved neurofunctional outcomes and cognitive performance. These findings highlight the nanoparticles' role as effective modulators of CRM1-mediated PKM2 nuclear translocation, with significant implications for mitigating neuroinflammation and neuronal apoptosis. Together with exercise, this dual-modality approach could offer new avenues for enhancing cognitive performance and neurofunctional outcomes in AD, marking a promising step forward in developing treatment strategies for this challenging disorder.

Topics & Concepts

NeuroinflammationPharmacologyDementiaAlzheimer's diseaseNeuroscienceLiposomeMedicineChromosomal translocationDiseaseBioinformaticsBiologyInternal medicineBiochemistryGeneAlzheimer's disease research and treatmentsGenetics and Neurodevelopmental DisordersRNA regulation and disease