Loss of the lysosomal lipid flippase ATP10B leads to progressive dopaminergic neurodegeneration and Parkinsonian motor deficits

Background

ATP10B, a transmembrane lipid flippase located in late endosomes and lysosomes, facilitates the export of glucosylceramide and phosphatidylcholine by coupling this process to ATP hydrolysis. Recently, loss-of-function mutations in the ATP10B gene have been identified in Parkinson’s disease patients, pointing to ATP10B as a candidate genetic risk factor. Previous studies have shown compromised lysosomal functionality upon ATP10B knockdown in human cell lines and primary cortical neurons. However, its role in vivo and specifically in the nigrostriatal dopaminergic system in vivo remains poorly understood.

Methods

To investigate the role ATP10B in PD neuropathology, we induced ATP10B knockdown specifically in substantia nigra pars compacta neurons of rats using viral vector technology. Two different microRNA-based shRNA constructs targeting distinct regions of the ATP10B mRNA were used to cross validate the findings. Behavioral evaluation, dopamine transporter ¹⁸F-FE-PE2I positron emission tomography imaging and neuropathological examination of the nigrostriatal pathway at one year post-injection were conducted. Additionally, midbrain neuronal cultures derived from ATP10B knock-out human induced pluripotent stem cells clones were used to study the impact of ATP10B loss in dopaminergic neurons in a more translational model.

Results

ATP10B knockdown in rat brain induced Parkinsonian motor deficits, and longitudinal-striatal dopamine transporter ¹⁸F-FE-PE2I PET imaging revealed a progressive decrease in binding potential. Immunohistochemical analysis conducted one year post-injection confirmed the loss of dopaminergic terminals in the striatum, alongside a loss of dopaminergic neurons in the substantia nigra pars compacta. The expression of LAMP1, LAMP2a, cathepsin B and glucocerebrosidase was studied by immunofluorescence in the surviving dopaminergic neurons. A decrease of lysosomal numbers and an increase in lysosomal volume were observed more consistently in one of the knockdown constructs. The vulnerability of dopaminergic neurons to ATP10B loss-of-function was also observed in midbrain neuronal cultures derived from ATP10B knock-out human induced pluripotent stem cells clones, which showed a significant reduction in TH-positive neurons.

Conclusion

Taken together, our findings demonstrate that ATP10B depletion detrimentally impacts the viability of dopaminergic neurons both in vivo and in vitro. Moreover, a broader impact on the functionality of the nigrostriatal pathway was evidenced as rats with ATP10B knockdown exhibited motor impairments similar to those observed in PD patients.