The secreted neuronal signal Spock1 regulates the blood-brain barrier

The blood-brain barrier (BBB) is comprised of a single layer of endothelial cells with uniquely restrictive properties required for maintaining a tightly controlled homeostatic environment in the brain. Classic quail-chick grafting experiments showed that BBB properties are not intrinsic to brain endothelial cells, but instead are induced by signals from the embryonic brain microenvironment. Here we have identified a neuronally produced signal, Spock1, that specifically regulates BBB functional development in both zebrafish and mice without affecting angiogenesis. Using a combination of mosaic genetic analysis, tracer leakage assays and live imaging we show that Spock1 from neurons can regulate brain vasculature permeability non-cell autonomously. Electron microscopy analyses of spock1 mutants revealed that the leakage arises predominantly through increased endothelial transcytosis of both clathrin-independent small and large vesicles due to altered pericyte-endothelial interactions. Single-cell RNA sequencing analyses revealed a reduction in vascular expression of the cell adhesion molecule mcamb in the spock1 mutants, and this down-regulation of mcamb occurred specifically in regions with increased BBB leakage. These analyses indicate that the neuronal signal Spock1 regulates BBB properties by altering vascular gene expression and cellular interactions. ### Competing Interest Statement The authors have declared no competing interest.