Mutation in presynaptic protein Bassoon induces tauopathy in vivo

Abstract

AbstractBackgroundTau aggregation is the underlying cause of several neurodegenerative tauopathies. Formation of tau aggregates with seeding activity involves interactions with other proteins, but with unknown effects on tau‐seed properties. Our previous study found that Bassoon (BSN), a presynaptic protein, interacts with tau‐seed, exacerbating its toxicity in vivo. Bsn downregulation reduced tau spreading and overall pathology. A previous study also linked missense mutations in BSN to the aggregation of 3‐ and 4‐repeat tau in patients. However, it is unknown how genetic mutations in BSN influence tau pathology in vivo.MethodWe developed a knock‐in mouse model harboring a mutation in endogenous BSN (p.Pro3882Ala), equivalent to p.Pro3866Ala BSN mutation identified in patients. We evaluated the cognitive and motor abilities of aged heterozygous and homozygous BSNKI mice and also we analyzed BSN and tau patterns in the brains of these mice. Additionally, we examined BSN and tau patterns in the BSN mutation carrier.ResultAt 10 months, BSNKI mice did not exhibit anxiety‐related behavior and had similar activity as WT littermates. They also displayed similar cognitive abilities as the WT mice. Interestingly, the BSNKI mice displayed lower latency to fall off the rotarod and reduced grip strength compared to the WT mice. We also observed an increase in the accumulation of pathological tau and BSN deposits in the brains of the BSNKI mice. The BSN mutation carrier displayed inclusions of BSN and tau pathology.ConclusionWe developed a mouse model with a knock‐in mutation in the Bassoon gene, allowing us to evaluate the effects of this disease‐associated mutation in vivo. Our results have shown that the mice with Bsn mutation have impairments in motor coordination, and postural instability, similar to BSN mutation carriers and show pathological tau and BSN deposits in the brain. We found inclusions of BSN and tau pathology in BSN mutation the carrier that resembled certain pathological features of AD and PSP. These findings suggest that BSN plays a role in tau pathology and targeting it may represent a promising therapeutic strategy for tauopathies. Further research is needed to fully understand our findings' underlying mechanisms and potential therapeutic implications.