The main aims of B3M are (1) the establishment of a 3D model of brain blood vessels that resemble those in vivo both in terms of cellular and BM layers and which are in an environment that resembles the (low) stiffness of the brain parenchyma, and (2) to dissect the steps in leukocyte extravasation using a series of novel in vitro set ups, that will allow precise investigation of steps that would otherwise remain difficult to assess (events occurring after penetration of the endothelium and before entry into the inflamed brain).
The project comprises 5 WPs, all of which have commenced and are progressing according to plan. WP1 focuses on development of a 3D model of cerebral microvessels using a novel dextran-hydrogel system, and has to date established the conditions needed for both formation of an endothelial monolayer with a basal BM and for spreading and polarization of astrocytes (Fig. 2). A protocol for iPSC differentiation to brain-like endothelial cells has been established, which differs to others to date in that it maintains the endothelial molecular profile but promotes the tight junctional interactions and barrier formation, typical of brain endothelium. This now permits testing of iPSC derived brain-like endothelial cells in the 3D dextran hydrogels together with astrocytes and pericytes or conditioned medium thereof.
WP2 and WP3 address the mechanical aspects of the subendothelial niche and penetration of the BM, respectively. A breakthrough has been the development of the first in vitro system for visualisation of leukocyte migration across excised BMs. This now permits precise investigation of both leukocytes and the BM during the extravasation processes and dissection of factors such as tension across the BM, receptors on the leukocytes, involvement of proteases, and signalling cascades in leukocytes required for penetration of the BM.
Parallel in vivo analyses have addressed the role of vascular BMs on the maintenance of perivascular myeloid populations, which have recently received considerable attention but the function of which remains unclear. Our data provide new information demonstrating that interactions between perivascular laminins myeloid precursor affect their development and the seeding of the meningeal and perivascular niches, and that they are required for the long term survival of perivascular macrophages.