In Alzheimer's disease (AD) more than 50% of the patients are affected by capillary cerebral amyloid-angiopathy (capCAA), which is characterized by localized hypoxia, neuro-inflammation and loss of bl Show more
In Alzheimer's disease (AD) more than 50% of the patients are affected by capillary cerebral amyloid-angiopathy (capCAA), which is characterized by localized hypoxia, neuro-inflammation and loss of blood-brain barrier (BBB) function. Moreover, AD patients with or without capCAA display increased vessel number, indicating a reactivation of the angiogenic program. The molecular mechanism(s) responsible for BBB dysfunction and angiogenesis in capCAA is still unclear, preventing a full understanding of disease pathophysiology. The Liver X receptor (LXR) family, consisting of LXRα and LXRβ, was reported to inhibit angiogenesis and particularly LXRα was shown to secure BBB stability, suggesting a major role in vascular function. In this study, we unravel the regulatory mechanism exerted by LXRα to preserve BBB integrity in human brain endothelial cells (BECs) and investigate its role during pathological conditions. We report that LXRα ensures BECs identity via constitutive inhibition of the transcription factor SNAI2. Accordingly, deletion of brain endothelial LXRα is associated with impaired DLL4-NOTCH signalling, a critical signalling pathway involved in vessel sprouting. A similar response was observed when BECs were exposed to hypoxia, with concomitant LXRα decrease and SNAI2 increase. In support of our cell-based observations, we report a general increase in vascular SNAI2 in the occipital cortex of AD patients with and without capCAA. Importantly, SNAI2 strongly associated with vascular amyloid-beta deposition and angiopoietin-like 4, a marker for hypoxia. In hypoxic capCAA vessels, the expression of LXRα may decrease leading to an increased expression of SNAI2, and consequently BECs de-differentiation and sprouting. Our findings indicate that LXRα is essential for BECs identity, thereby securing BBB stability and preventing aberrant angiogenesis. These results uncover a novel molecular pathway essential for BBB identity and vascular homeostasis providing new insights on the vascular pathology affecting AD patients. Show less
Susceptibility to chemically induced lung tumorigenesis has previously been mapped to a genomic interval of 27 kb in the MHC class III region of the mouse using two H2 (a/b) intra- H2 recombinants, B1 Show more
Susceptibility to chemically induced lung tumorigenesis has previously been mapped to a genomic interval of 27 kb in the MHC class III region of the mouse using two H2 (a/b) intra- H2 recombinants, B10.A(1R) and B10.A(2R). Three genes are located within this interval, G7e (encoding a viral envelope protein), G7a/ Vars2 (encoding valyl-tRNA synthetase), and G7c (a gene with unknown function). A 70 kb contig, spanning the 27 kb region and extending 20 kb either side, was constructed from lambda phage libraries with genomic inserts derived from mouse strains B10.A(1R) and B10.A(2R). The region was analyzed for single-nucleotide polymorphisms, which would facilitate further fine mapping of the interval. Analysis of the expression levels of the candidate genes did not reveal any difference between B10.A(1R) and B10.A(2R). In addition, no differences were found at the sequence level in the 27 kb interval except for an A to T transition in intron 7 of G7c. A database comparison of the sequence surrounding this polymorphism did not identify any DNA-binding or enhancer consensus sequence. In conclusion, the previously observed phenotype could not be associated with or assigned to any of the candidate genes G7e, G7a/ Vars2, or G7c, nor could any of the other susceptibility loci, which have been reported to map to this region ( Cps1, Acp, Orch1, and Igis1). Show less