In the ClearPath project, we successfully differentiated iPSC lines into functional brain endothelial cells, validating their barrier phenotype through tight junction marker expression and TEER measurements. This enabled the establishment of an in vitro BBB model, which was subsequently used to perform permeability assays and investigate the effect of Aβ exposure on barrier integrity.
In parallel, using endothelial cells such as HUVECs and commercially available Human Brain Microvascular Endothelial Cells (HBMVECs), we investigated Aβ uptake and transport across the endothelial layer, confirming the suitability of our model for mechanistic clearance studies.
The fellow completed a short-term secondment at Johns Hopkins School of Medicine, acquiring hands-on training in hiPSC differentiation and maintenance. This training was critical for implementing advanced stem cell methodologies and directly contributed to the successful establishment of the BBB model at BRI-FORTH.
Using the in vitro BBB models, we systematically investigated the endocytic routes of Aβ uptake in brain endothelial cells. Confocal imaging and colocalization studies demonstrated that Aβ is internalized, in part, through macropinocytosis, as indicated by its overlap with dextran-positive vesicles.
Complementary bioinformatics analyses were performed using large-scale genome-wide datasets, including single-nucleus transcriptomes from AD patients, with a focus on brain endothelial cells. A second short-term secondment at the Department of Bioinformatics, Ionian University (Corfu, Greece), provided training in the biological interpretation of large gene lists. This analysis identified potential pathogenic factors, differentially expressed genes, and novel associations between AD and specific genes. Candidate genes will be further validated using the established in vitro BBB models.
To confirm the contribution of endocytic pathways to Aβ clearance, we employed in vivo models, including C. elegans expressing pan-neuronal human Aβ1–42 (CL2355) and the 5XFAD transgenic mouse model, widely used in AD research.
Overall, the ClearPath project demonstrated the originality and strength of integrating multidisciplinary techniques, combining iPSC technology from AD patients, advanced molecular and cellular biology, bioinformatic analysis of large-scale omics data, and in vivo model organisms to address key questions regarding Aβ clearance and BBB function.