Cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL) is caused by mutations in the NOTCH3 gene. Previous research has predominantly focused on vascular smooth muscle cell pathology, whereas the role of brain microvascular endothelial cells (BMECs) in the disease remains unclear.
Objective
To investigate the impact of the NOTCH3-R544C mutation on BMECs function and to elucidate the underlying mechanisms of endothelial dysfunction in CADASIL.
Methods
Using CADASIL transgenic mice and endothelial cell (EC) models stably expressing NOTCH3-R544C, the impact of the mutation on endothelial function was assessed through immunofluorescence staining, RNA-seq analysis, protein-protein interaction (PPI) network mapping, and lipid and cellular function assays.
Results
Significant NOTCH3 extracellular domain (NOTCH3ECD) deposition and reduced microvascular density are observed in CADASIL mice. R544C mutant cells exhibit abnormal NOTCH3ECD accumulation alongside pronounced gene expression dysregulation, predominantly enriched in pathways related to inflammation, cell migration. The PPI network centers on CXCL10 as a pivotal hub, forming a core “inflammation-migration” pathological axis. R544C cells exhibit heightened inflammatory responses, cholesterol accumulation, reduced cell viability, and increased sensitivity to inflammatory stimuli.
Conclusions
The NOTCH3-R544C mutation disrupts inflammatory regulation, migratory capacity, and lipid metabolic homeostasis in BMECs, leading to endothelial dysfunction and revealing a key mechanism of endothelial injury in CADASIL.
ChabriatHJoutelADichgansM, et al.Cadasil. Lancet Neurol2009; 8: 643–653.
2.
SchonFMartinRJPrevettM, et al."CADASIL Coma": an underdiagnosed acute encephalopathy. J Neurol Neurosurg Psychiatry2003; 74: 249–252.
3.
CharltonRAMorrisRGNitkunanA, et al.The cognitive profiles of CADASIL and sporadic small vessel disease. Neurology2006; 66: 1523–1526.
4.
HarrazOFLongdenTADabertrandF, et al.Endothelial GqPCR activity controls capillary electrical signaling and brain blood flow through PIP(2) depletion. Proc Natl Acad Sci U S A2018; 115: E3569–e3577.
5.
GueySMawetJHervéD, et al.Prevalence and characteristics of migraine in CADASIL. Cephalalgia2016; 36: 1038–1047.
6.
ValentiRPoggesiAPesciniF, et al.Psychiatric disturbances in CADASIL: a brief review. Acta Neurol Scand2008; 118: 291–295.
7.
OpherkCDueringMPetersN, et al.CADASIL Mutations enhance spontaneous multimerization of NOTCH3. Hum Mol Genet2009; 18: 2761–2767.
8.
DueringMKarpinskaARosnerS, et al.Co-aggregate formation of CADASIL-mutant NOTCH3: a single-particle analysis. Hum Mol Genet2011; 20: 3256–3265.
9.
JoutelAAndreuxFGaulisS, et al.The ectodomain of the Notch3 receptor accumulates within the cerebrovasculature of CADASIL patients. J Clin Invest2000; 105: 597–605.
10.
SiebelCLendahlU. Notch signaling in development, tissue homeostasis, and disease. Physiol Rev2017; 97: 1235–1294.
11.
AnderssonERSandbergRLendahlU. Notch signaling: simplicity in design, versatility in function. Development2011; 138: 3593–3612.
12.
CouplandKLendahlUKarlströmH. Role of NOTCH3 mutations in the cerebral small vessel disease cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy. Stroke2018; 49: 2793–2800.
13.
HainsworthAHOommenATBridgesLR. Endothelial cells and human cerebral small vessel disease. Brain Pathol2015; 25: 44–50.
14.
RuchouxMMMaurageCA. Endothelial changes in muscle and skin biopsies in patients with CADASIL. Neuropathol Appl Neurobiol1998; 24: 60–65.
15.
StenborgAKalimoHViitanenM, et al.Impaired endothelial function of forearm resistance arteries in CADASIL patients. Stroke2007; 38: 2692–2697.
16.
JoutelAMonet-LeprêtreMGoseleC, et al.Cerebrovascular dysfunction and microcirculation rarefaction precede white matter lesions in a mouse genetic model of cerebral ischemic small vessel disease. J Clin Invest2010; 120: 433–445.
17.
ZhangWZhaoXQiX, et al.Induced pluripotent stem cell model revealed impaired neurovascular interaction in genetic small vessel disease cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy. Front Cell Neurosci2023; 17: 1195470.
18.
AndreoneBJChowBWTataA, et al.Blood-brain barrier permeability is regulated by lipid transport-dependent suppression of caveolae-mediated transcytosis. Neuron2017; 94: 581–594.e585.
KunduMGreerYELobanovA, et al.TRAIL Induces cytokine production via the NFkB2 pathway promoting neutrophil chemotaxis and neutrophil-mediated immune-suppression in triple negative breast cancer cells. Cancer Lett2025; 620: 217692.
25.
XiangMShiXLiY, et al.Hemorrhagic shock activation of NLRP3 inflammasome in lung endothelial cells. J Immunol2011; 187: 4809–4817.
26.
LingXWeiSLingD, et al.Irf7 regulates the expression of Srg3 and ferroptosis axis aggravated sepsis-induced acute lung injury. Cell Mol Biol Lett2023; 28: 91.
27.
ChenLDaiMZuoW, et al.NF-κB p65 and SETDB1 expedite lipopolysaccharide-induced intestinal inflammation in mice by inducing IRF7/NLR-dependent macrophage M1 polarization. Int Immunopharmacol2023; 115: 109554.
28.
TuoYGuoXZhangX, et al.The biological effects and mechanisms of calcitonin gene-related peptide on human endothelial cell. J Recept Signal Transduct Res2013; 33: 114–123.
29.
PatanS. Vasculogenesis and angiogenesis. Cancer Treat Res2004; 117: 3–32.
30.
JalaliBMLikszoPLukasikK. STAT3 In porcine endometrium during early pregnancy induces changes in extracellular matrix components and promotes angiogenesisdagger. Biol Reprod2022; 107: 1503–1516.
31.
RasouliAYuQDehghani-GhahnaviyehS, et al.Differential dynamics and direct interaction of bound ligands with lipids in multidrug transporter ABCG2. Proc Natl Acad Sci U S A2023; 120: e2213437120.
32.
IwaiMTulafuMTogoS, et al.Cancer-associated fibroblast migration in non-small cell lung cancers is modulated by increased integrin alpha11 expression. Mol Oncol2021; 15: 1507–1527.
33.
WangLTangYTangJ, et al.Endothelial cell-derived extracellular vesicles expressing surface VCAM1 promote sepsis-related acute lung injury by targeting and reprogramming monocytes. J Extracell Vesicles2024; 13: e12423.
34.
QiWXuQXuY, et al.Effect of Notch pathway on lipid accumulation induced by mono-2-ethylhexyl phthalate on 3T3-L1 cells. Ecotoxicol Environ Saf2021; 208: 111472.
35.
LiNZhuCFuR, et al.Ginsenoside Rg5 inhibits lipid accumulation and hepatocyte apoptosis via the Notch1 signaling pathway in NASH mice. Phytomedicine2024; 124: 155287.
36.
Madduma HewageSAu-YeungKKWPrasharS, et al.Lingonberry improves hepatic lipid metabolism by targeting Notch1 signaling. Antioxidants (Basel)2022; 11: 472.
37.
SucklingRJKoronaBWhitemanP, et al.Structural and functional dissection of the interplay between lipid and Notch binding by human Notch ligands. EMBO J2017; 36: 2204–2215.
38.
QuaziFMoldayRS. Lipid transport by mammalian ABC proteins. Essays Biochem2011; 50: 265–290.
39.
CaoCShiYZhangX, et al.Cholesterol-induced LRP3 downregulation promotes cartilage degeneration in osteoarthritis by targeting Syndecan-4. Nat Commun2022; 13: 7139.
40.
KhalilYARabesJPBoileauC, et al.APOE Gene variants in primary dyslipidemia. Atherosclerosis2021; 328: 11–22.
41.
GuoJLBraunDFitzgeraldGA, et al.Decreased lipidated ApoE-receptor interactions confer protection against pathogenicity of ApoE and its lipid cargoes in lysosomes. Cell2025; 188: 187–206.e126.
42.
RassartEDesmaraisFNajybO, et al.Apolipoprotein D. Gene2020; 756: 144874.
43.
SchadeDSSheyLEatonRP. Cholesterol review: a metabolically important molecule. Endocr Pract2020; 26: 1514–1523.
44.
LeeYCLiuCSChangMH, et al.Population-specific spectrum of NOTCH3 mutations, MRI features and founder effect of CADASIL in Chinese. J Neurol2009; 256: 249–255.
45.
KimYEYoonCWSeoSW, et al.Spectrum of NOTCH3 mutations in Korean patients with clinically suspicious cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy. Neurobiol Aging2014; 35: 726.e721–726.
46.
KalimoHRuchouxMMViitanenM, et al.CADASIL: a common form of hereditary arteriopathy causing brain infarcts and dementia. Brain Pathol2002; 12: 371–384.
47.
JoutelACorpechotCDucrosA, et al.Notch3 mutations in CADASIL, a hereditary adult-onset condition causing stroke and dementia. Nature1996; 383: 707–710.
48.
JoutelAFavrolePLabaugeP, et al.Skin biopsy immunostaining with a Notch3 monoclonal antibody for CADASIL diagnosis. Lancet2001; 358: 2049–2051.
49.
DichgansMLudwigHMüller-HöckerJ, et al.Small in-frame deletions and missense mutations in CADASIL: 3D models predict misfolding of Notch3 EGF-like repeat domains. Eur J Hum Genet2000; 8: 280–285.
50.
GhoshMBalbiMHellalF, et al.Pericytes are involved in the pathogenesis of cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy. Ann Neurol2015; 78: 887–900.
51.
DubrocaCLacombePDomengaV, et al.Impaired vascular mechanotransduction in a transgenic mouse model of CADASIL arteriopathy. Stroke2005; 36: 113–117.
52.
RuchouxMMChabriatHBousserMG, et al.Presence of ultrastructural arterial lesions in muscle and skin vessels of patients with CADASIL. Stroke1994; 25: 2291–2292.
53.
LingCLiuZSongM, et al.Modeling CADASIL vascular pathologies with patient-derived induced pluripotent stem cells. Protein Cell2019; 10: 249–271.
54.
LiuHKennardSLillyB. NOTCH3 Expression is induced in mural cells through an autoregulatory loop that requires endothelial-expressed JAGGED1. Circ Res2009; 104: 466–475.
55.
LiuHZhangWKennardS, et al.Notch3 is critical for proper angiogenesis and mural cell investment. Circ Res2010; 107: 860–870.
