Knockdown of POLG Mimics the Neuronal Pathology of Polymerase-γ Spectrum Disorders in Human Neurons.

Impaired function of Polymerase-γ (Pol-γ) results in impaired replication of the mitochondrial genome (mtDNA). Pathogenic mutations in the POLG gene cause dysfunctional Pol-γ and dysfunctional mitochondria and are associated with a spectrum of neurogenetic disorders referred to as POLG spectrum disorders (POLG-SDs), which are characterized by neurologic dysfunction and premature death. Pathomechanistic studies and human cell models of these diseases are scarce. SH-SY5Y cells (SHC) are an easy-to-handle and low-cost human-derived neuronal cell model commonly used in neuroscientific research. Here, we aimed to study the effect of reduced Pol-γ function using stable lentivirus-based shRNA-mediated knockdown of POLG in SHC, in both the proliferating cells and SHC-derived neurons. POLG knockdown resulted in approximately 50% reductions in POLG mRNA and protein levels in naïve SHC, mimicking the residual Pol-γ activity observed in patients with common pathogenic POLG mutations. Knockdown cells exhibited decreased mtDNA content, reduced levels of mitochondrial-encoded proteins, and altered mitochondrial morphology and distribution. Notably, while chemical induction of mtDNA depletion via ddC could be rescued by the mitochondrial biosynthesis stimulators AICAR, cilostazol and resveratrol (but not MitoQ and formoterol) in control cells, POLG-knockdown cells were resistant to mitochondrial biosynthesis-mediated induction of mtDNA increase, highlighting the specificity of the model, and pathomechanistically hinting towards inefficiency of mitochondrial stimulation without sufficient Pol-γ activity. In differentiated SHC-derived human neurons, POLG-knockdown cells showed impaired neuronal differentiation capacity, disrupted cytoskeletal organization, and abnormal perinuclear clustering of mitochondria. In sum, our model not only recapitulates key features of POLG-SDs such as impaired mtDNA content, which cannot be rescued by mitochondrial biosynthesis stimulation, but also reduced ATP production, perinuclear clustering of mitochondria and impaired neuronal differentiation. It also offers a simple, cost-effective and human (and, as such, disease-relevant) platform for investigating disease mechanisms, one with screening potential for therapeutic approaches for POLG-related mitochondrial dysfunction in human neurons.