Loss of angiopoietin-2 leads to region-specific brain malformations and blood-brain barrier leakage
Weihan Li, Elisa Vázquez-Liébanas, Chanaëlle Fébrissy, Florent Sauvé, Jianhao Wang, Doğan E. Sayıner, Pia Buslaps, Amanda Norrén, Michael Vanlandewijck, Liqun He, Marie Jeansson, Lars Muhl, Maarja Andaloussi Mäe
Weihan Li, Elisa Vázquez-Liébanas, Chanaëlle Fébrissy, Florent Sauvé, Jianhao Wang, Doğan E. Sayıner, Pia Buslaps, Amanda Norrén, Michael Vanlandewijck, Liqun He, Marie Jeansson, Lars Muhl, Maarja Andaloussi Mäe
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Research Article Cell biology Vascular biology

Loss of angiopoietin-2 leads to region-specific brain malformations and blood-brain barrier leakage

Abstract

Angiopoietin-2 (ANGPT2) is known to destabilize vascular barriers in most peripheral organs; however, its role in the brain vasculature remains poorly understood. To investigate its physiological function within the brain vasculature, we analyzed constitutive Angpt2-knockout mice in adulthood. We showed that loss of ANGPT2 leads to region-specific vascular malformations and blood-brain barrier (BBB) dysfunction, resulting in differential permeability to 1 kDa and 70 kDa fluorescent tracers. Notably, overt vascular malformations appeared only in select brain regions that allowed leakage of both tracers. These malformations were characterized by dilated, intertwined, and sprouting endothelial cells, surrounded by reactive perivascular cells, along with high levels of astrocyte- and neuron-derived vascular endothelial growth factor A (VEGFA) and elevated expression of the vascular receptors VEGF receptor 2 (KDR) and neuropilin-1 (NRP1). Other cortical areas without obvious malformations exhibited significant leakage of the 1 kDa tracer. We also demonstrated that different cell types took up the tracers after passing the BBB. Our findings identified ANGPT2 as an important factor involved in the regulation of cerebrovascular architecture, barrier integrity, and endothelial-parenchymal interactions, and uncovered surprising differences in the leakage patterns and cellular uptake of two widely used BBB tracers.

Authors

Weihan Li, Elisa Vázquez-Liébanas, Chanaëlle Fébrissy, Florent Sauvé, Jianhao Wang, Doğan E. Sayıner, Pia Buslaps, Amanda Norrén, Michael Vanlandewijck, Liqun He, Marie Jeansson, Lars Muhl, Maarja Andaloussi Mäe

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Figure 5

ScRNA-seq analysis in Angpt2-WT and -KO mice.

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ScRNA-seq analysis in Angpt2-WT and -KO mice. (A) UMAP of EC dataset, cl...
(A) UMAP of EC dataset, clustered into 7 clusters (0 to 6) at a resolution of 0.4. (B) Proportion of ECs in each cluster (0 to 6). (C) UMAPs of the cell clusters from each sample. (D) UMAPs showing the expression of arteriovenous markers. (E) Top 10 GO biological process terms overrepresented in cluster 4. Count = number of genes per term. (F) Representative images of NRP1 (red), ERG (cyan), and PECAM1 (gray) IF in CP (n = 3). High-magnification images of 1 Z-plane magnification of tangled vasculature with EC and perivascular NRP1 expression (yellow arrowheads [i] and NRP1+ dilated vasculature [ii]). Scale bars: 25 μm (F); 50 μm (G). (G) Representative images of NRP1 (cyan), PDGFRB (red), and COLIV (yellow) IF in CP (n = 3). High-magnification images of 1 Z-plane magnification of the dilated vasculature. NRP1+/PDGFRB+ cells (red arrowheads); NRP1+ cells outside the collagen sleeve (white arrowheads). Scale bars: 50 μm. (H) UMAPs of Angpt2 expression. (I) Relative mRNA expression of Angpt2 exons in adult brain microvascular fragments from WT (light blue) and KO (dark blue) mice (n = 3). Shown values are 2–ΔCt of Gapdh. Data were normally distributed, and a Welch’s t test was performed to evaluate significance. *P < 0.05, **P < 0.01.