Cerebral cavernous malformations form an anticoagulant vascular domain in humans and mice

Lopez-Ramirez, Miguel Alejandro; Pham, Angela; Girard, Romuald; Wyseure, Tine; Hale, Preston; Yamashita, Atsuki; Koskimäki, Janne; Polster, Sean P.; Saadat, Laleh; Romero, Ignacio A.; Esmon, Charles T.; Lagarrigue, Frédéric; Awad, Issam A.; Mosnier, Laurent O.; Ginsberg, Mark H.

doi:10.1182/blood-2018-06-856062

Cited by 65 publications

(90 citation statements)

References 50 publications

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“…The expression of typical lesion markers Klf4 , Ly6a , and Thbd ( Maddaluno et al, 2013 ; Lopez-Ramirez et al, 2019 ) was higher for the Pdcd10 -ko cells specific to the S0–S2 and S3–S0 branches, even if not exclusively limited to these branches ( Figure 6D ).…”

Section: Resultsmentioning

confidence: 99%

Mapping endothelial-cell diversity in cerebral cavernous malformations at single-cell resolution

Orsenigo

Conze

Jauhiainen

et al. 2020

eLife

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Cerebral cavernous malformation (CCM) is a rare neurovascular disease that is characterized by enlarged and irregular blood vessels that often lead to cerebral hemorrhage. Loss-of-function mutations to any of three genes results in CCM lesion formation; namely, KRIT1, CCM2, and PDCD10 (CCM3). Here, we report for the first time in-depth single-cell RNA sequencing, combined with spatial transcriptomics and immunohistochemistry, to comprehensively characterize subclasses of brain endothelial cells (ECs) under both normal conditions and after deletion of Pdcd10 (Ccm3) in a mouse model of CCM. Integrated single-cell analysis identifies arterial ECs as refractory to CCM transformation. Conversely, a subset of angiogenic venous capillary ECs and respective resident endothelial progenitors appear to be at the origin of CCM lesions. These data are relevant for the understanding of the plasticity of the brain vascular system and provide novel insights into the molecular basis of CCM disease at the single cell level.

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Section: Resultsmentioning

confidence: 99%

Mapping endothelial-cell diversity in cerebral cavernous malformations at single-cell resolution

Orsenigo

Conze

Jauhiainen

et al. 2020

eLife

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“…Moreover, HEG1 mutations have never been identified in human CCM and deletion of HEG1 in mice does not cause CCM (1). Here we developed a method for pharmacological inhibition of the HEG1-KRIT1 protein-protein interaction and found the predicted upregulation of KLF4 and KLF2 gene expression, and expected effects on some of their target genes such as THSP1 and THBD, as we previously observed with knockdown of KRIT1 in EC (9,29). Moreover, KLF4/2 were upregulated within 4 hr of drug addition, a time long before acute genetic inactivation of Krit1 would do so.…”

Section: Discussionmentioning

confidence: 62%

“…Many of the effects of pulsatile sheer stress (PS) are due to upregulation of transcription factors KLF4 and KLF2, which in turn can increase expression of genes that encode anticoagulant cofactors (e.g., THBD encoding thrombomodulin, TM) and suppress expression of genes that antagonize angiogenesis (e.g.,THBS1 encoding thrombospondin1, TSP1). Thus, PS can upregulate KLF4/2 in endothelium and their important transcriptional targets (9,(24)(25)(26)(27)(28)(29).…”

Section: Discussionmentioning

confidence: 99%

Pharmacological inhibition of the heart of glass (HEG1)-Krev interaction trapped protein 1 (KRIT1) protein complex increases Krüppel-like Factors 4 and 2 (KLF4/2) expression in endothelial cells

Lopez-Ramirez

Haynes

Hale

et al. 2019

Preprint

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The Krüppel-like Factors 4 and 2 (KLF4/2) are transcription factors and master regulators of endothelial cells (ECs) phenotype and homeostasis. KLF4/2 are important blood-flow-responsive genes within ECs that differentially regulate the expression of factors that confer anti-inflammatory, antithrombotic, and antiproliferative effects in ECs. Genetic inactivation of endothelial KRIT1 (Krev interaction trapped protein 1) or HEG1 (Heart of glass) lead to upregulation of KLF4/2 expression levels. Furthermore, increased expression of thrombomodulin (THBD) and suppression of thrombospondin (THBS1) was ascribed to elevation of KLF4/2 as a result of loss of endothelial KRIT1. Here, we developed a highthroughput screening assay to identify inhibitors of the HEG1-KRIT1 interaction and identified, HEG1-KRIT1 inhibitor 1 (HKi1), as a promising hit inhibitor. The crystal structure of HKi1 bound to the KRIT1 FERM domain confirmed the primary screening results and ultimately led to the identification of a fragment-like inhibitor (HKi3), which occupies the HEG1 pocket producing comparable activity. These findings suggest that these inhibitors block theinteraction by competing with the HEG1 for binding toKRIT1 FERM domain. Moreover, our results demonstrate thatHKi3 upregulates KLF4/2 gene expression in two types of human ECs. These results reveal that acute pharmacological inhibition of the HEG1-KRIT1 interaction rapidly induces expression of KLF4/2 and their important transcriptional targets thrombomodulin and thrombospondin.

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“…65,93 Other signaling aberrations involve dysangiogenesis; 46,107 endothelial-mesenchymal transition; 60 proinflammatory state, oxidative stress, and autophagy; 70,76 loss of TSP1; 56 and thrombomodulinassociated local anticoagulant domains. 57 Lesion development is also driven by lipid polysaccharide signaling through CD14/TLR4 receptors on brain microvascular ECs, and this has been related to a robust impact of gramnegative bacteria in the gut microbiome on lesion development. 97 Heterozygous CCM mutations have been correlated with increased vascular permeability in the skin, lung, and brain, 93,103 even in the absence of lesions, which has been confirmed in humans.…”

Section: Consequences Of Ccm Gene Lossmentioning

confidence: 99%

Cavernous angiomas: deconstructing a neurosurgical disease

Awad

Polster

2019

Journal of Neurosurgery

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Cavernous angioma (CA) is also known as cavernoma, cavernous hemangioma, and cerebral cavernous malformation (CCM) (National Library of Medicine Medical Subject heading unique ID D006392). In its sporadic form, CA occurs as a solitary hemorrhagic vascular lesion or as clustered lesions associated with a developmental venous anomaly. In its autosomal dominant familial form (Online Mendelian Inheritance in Man #116860), CA is caused by a heterozygous germline loss-of-function mutation in one of three genes—CCM1/KRIT1, CCM2/Malcavernin, and CCM3/PDCD10—causing multifocal lesions throughout the brain and spinal cord.In this paper, the authors review the cardinal features of CA’s disease pathology and clinical radiological features. They summarize key aspects of CA’s natural history and broad elements of evidence-based management guidelines, including surgery. The authors also discuss evidence of similar genetic defects in sporadic and familial lesions, consequences of CCM gene loss in different tissues at various stages of development, and implications regarding the pathobiology of CAs.The concept of CA with symptomatic hemorrhage (CASH) is presented as well as its relevance to clinical care and research in the field. Pathobiological mechanisms related to CA include inflammation and immune-mediated processes, angiogenesis and vascular permeability, microbiome driven factors, and lesional anticoagulant domains. These mechanisms have motivated the development of imaging and plasma biomarkers of relevant disease behavior and promising therapeutic targets.The spectrum of discoveries about CA and their implications endorse CA as a paradigm for deconstructing a neurosurgical disease.

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Cerebral cavernous malformations form an anticoagulant vascular domain in humans and mice

Cited by 65 publications

References 50 publications

Mapping endothelial-cell diversity in cerebral cavernous malformations at single-cell resolution

Mapping endothelial-cell diversity in cerebral cavernous malformations at single-cell resolution

Pharmacological inhibition of the heart of glass (HEG1)-Krev interaction trapped protein 1 (KRIT1) protein complex increases Krüppel-like Factors 4 and 2 (KLF4/2) expression in endothelial cells

Cavernous angiomas: deconstructing a neurosurgical disease

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