Signalling pathways associated with impaired angiogenesis in Alzheimer’s Disease

Abstract

AbstractBackgroundBrain perfusion and blood brain barrier (BBB) integrity are reduced in Alzheimer’s disease (AD). We hypothesized that b‐amyloid (Aβ) induces dysfunction of pathways in vascular cells that regulate angiogenesis.MethodWe performed single nucleus RNA sequencing (snRNAseq) of vascular cells isolated from post mortem samples from multiple cortical regions from AD patients (Braak V‐VI) and non‐diseased controls (NDC, Braak 0‐II). We developed a meta‐analytic approach to integrate these data with related publicly available datasets. We performed differential gene expression (DGE) analyses as a categorical comparison of AD vs NDC and as a confound‐controlled regression of transcriptomic alterations by regional total Aβ. We also performed cell‐specific gene co‐expression analyses identify modules differentially expressed in AD relative to NDC.ResultOur results describe differential expression of genes central to pathways sustaining angiogenesis, proliferation and migration of endothelial cells and the integrity of the BBB with either AD or greater pathological protein load. HIF1A and FGF2, proangiogenic molecules which both induce VEGF, are upregulated in EC, consistent the parenchymal hypoxic response shown repeatedly in prior studies. However, components of signalling pathways downstream of VEGFR2 are downregulated, suggesting a pathological block to angiogenesis with greater Aβ load. While the proangiogenic stimuli promote the expression of genes such as PPP3CA and ITPR1, coding for calcineurin, which contribute to VEGF signalling through the PLCγ‐Ca2+ signalling pathway are upregulated in AD, expression of RAC1 and RHOJ, which enable cellular migration and adhesion, is downregulated. While ANGPT2 expression is also upregulated, the angiopoietin receptor (TIE2, coded by TEK) is downregulated. Downregulation of ADAM10 in AD and upregulation of other NOTCH pathway genes with greater Aβ load suggests altered NOTCH signalling.ConclusionOverall, a hypoxic tissue environment in AD is accompanied by dysfunctional angiogenesis related to Aβ load. Evidence for multiple sites of dysfunction were identified, involving impaired angiopoietin responses, vascular cell migration and NOTCH signaling.