In vivo validation of therapeutic efficacy of a small molecule lead targeting tau self‐association in JNPL3 mice

Background Small molecules were screened and optimized for inhibiting tau self‐association, the initial step in the formation of soluble toxic tau oligomers and larger insoluble aggregates. This approach is differentiated from other tau aggregation inhibitor programs that have largely focused on inhibiting formation and/or dissociating large and relatively inert fibrils which could generate toxic tau oligomer seeds. Small molecules inhibitors are agnostic to specific post‐translational modifications, conformational changes or strains of tau aggregates, and have superior access to their target in the CNS relative to immunotherapeutic approaches. We have previously shown in vivo efficacy of a lead compound in preventive studies in htau (Davidowitz et al., 2020) and human tau P301L JNPL3 mouse models of tauopathy. The tau P301L mutation is the most common FTDP‐17 mutation and causes tau aggregation and motor deficits with age (Lewis et al., 2000). Method Blinded studies of homozygous female tau 4R/0N P301L JNPL3 mice were performed at an independent laboratory where mice were treated for five months by administration of our lead compound in feed from 7 to 12 months‐of‐age. The four groups of mice in the study were baseline (7 months; n=20), vehicle, and two treatment groups (40 and 80 mg/kg doses; n=25 each). To quantify levels of Sarkosyl‐insoluble tau, self‐associated tau, and phosphorylated tau in the treated and control groups of mice ELISAs were performed (Acker et al., 2012; Forest et al., 2019). Rotarod and open field studies were performed to evaluate motor behavior. Result Efficacy was shown in the cortex of treated mice that had reduced levels of self‐associated tau below baseline, baseline levels of insoluble tau aggregates, and reduced levels of aberrantly phosphorylated tau with statistical significance. In the hindbrain there was reduction of insoluble tau aggregates in the 40 mg/kg group compared to vehicle. Treatment groups showed improved Rotarod performance compared to baseline and vehicle groups. Conclusion Treatment with the lead compound reduced tau aggregation and improved motor behavior in aged JNPL3 mice and support preclinical development of the lead for clinical studies.