Cerebral cavernous malformation proteins at a glance

Draheim, Kyle; Fisher, Oriana S.; Boggon, Titus J.; Calderwood, David A.

doi:10.1242/jcs.138388

Cited by 89 publications

(85 citation statements)

References 88 publications

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“…Normal endothelial basement membranes are composed mainly of collagen IV, laminin, and other glycoproteins and proteoglycans. Both flow-dependent remodeling and sprouting angiogenesis require proteolysis of this ECM and assembly of a fibronectin matrix (63)(64)(65) (108,110). Patients acquire sporadic lesions with age, presumably due to additional mutations or other local stresses, though these additional events are not well characterized.…”

Section: Plaque Progression and Remodelingmentioning

confidence: 99%

Endothelial fluid shear stress sensing in vascular health and disease

Baeyens

Bandyopadhyay

Coon

et al. 2016

Journal of Clinical Investigation

466

407

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Section: Plaque Progression and Remodelingmentioning

confidence: 99%

Endothelial fluid shear stress sensing in vascular health and disease

Baeyens

Bandyopadhyay

Coon

et al. 2016

Journal of Clinical Investigation

466

407

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“…However, KRIT1 is a multidomain protein that, in addition to having several other binding partners, contains two putative NLS and one predicted nuclear export signal (NES) (Fig. 7A) (17,28,30,43,44). To determine the localization of full-length KRIT1 (KRIT1 FL ) and the role of the predicted NLS and NES in the absence of co-expressed ICAP1, GFP-tagged KRIT1 was overexpressed in CHO cells (which do not express either endogenous ICAP1 or KRIT1 (45)).…”

Section: Binding To Icap1 Drives Nuclear Localization Of the Nterminamentioning

confidence: 99%

“…CCMs have been reported in up to 0.5% of the population (16) and are strongly associated with hemorrhagic stroke, seizure, epilepsy, and other focal neurological outcomes. CCMs are also caused by loss of function mutations in CCM2 or CCM3 genes (17), and the CCM2 protein can form the hub of a multiprotein KRIT1-CCM2-CCM3 complex: the CCM complex (12,18,19). Loss of KRIT1, CCM2, or CCM3 proteins is therefore directly associated with focal neurological defects, stroke, and vascular abnormalities.…”

mentioning

confidence: 99%

Nuclear Localization of Integrin Cytoplasmic Domain-associated Protein-1 (ICAP1) Influences β1 Integrin Activation and Recruits Krev/Interaction Trapped-1 (KRIT1) to the Nucleus

Draheim

Huet-Calderwood

Simon

et al. 2017

Journal of Biological Chemistry

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Edited by Thomas SöllnerBinding of ICAP1 (integrin cytoplasmic domain-associated protein-1) to the cytoplasmic tails of ␤1 integrins inhibits integrin activation. ICAP1 also binds to KRIT1 (Krev interaction trapped-1), a protein whose loss of function leads to cerebral cavernous malformation, a cerebrovascular dysplasia occurring in up to 0.5% of the population. We previously showed that KRIT1 functions as a switch for ␤1 integrin activation by antagonizing ICAP1-mediated inhibition of integrin activation. Here we use overexpression studies, mutagenesis, and flow cytometry to show that ICAP1 contains a functional nuclear localization signal and that nuclear localization impairs the ability of ICAP1 to suppress integrin activation. Moreover, we find that ICAP1 drives the nuclear localization of KRIT1 in a manner dependent upon a direct ICAP1/KRIT1 interaction. Thus, nuclear-cytoplasmic shuttling of ICAP1 influences both integrin activation and KRIT1 localization, presumably impacting nuclear functions of KRIT1.

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“…Mutations of the CCM3 gene have been linked to cerebral cavernous malformations -vascular abnormalities characterised by dilated leaky cerebral lesions that can lead to brain haemorrhage (Draheim et al, 2014). The exact mechanism by which cerebral cavernous malformations arise is still subject to debate, with deregulation of several signalling pathways such as RHO (Richardson et al, 2013;Stockton et al, 2010;Borikova et al, 2010;Whitehead et al, 2009), TGFβ (Maddaluno et al, 2013), β-catenin (Bravi et al, 2015) and MEKK3-KLF2 or MEKK3-KLF4 (Cuttano et al, 2016;Zhou et al, 2016;Renz et al, 2015) having been demonstrated to be involved in development and progression of the disease.…”

Section: E-2mentioning

confidence: 99%

RHO binding to FAM65A regulates Golgi reorientation during cell migration

Mardakheh¹,

Self²,

Marshall³

2017

Development

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Directional cell migration involves reorientation of the secretory machinery. However, the molecular mechanisms that control this reorientation are not well characterised. Here, we identify a new Rho effector protein, named FAM65A, which binds to active RHOA, RHOB and RHOC. FAM65A links RHO proteins to Golgi-localising cerebral cavernous malformation-3 protein (CCM3; also known as PDCD10) and its interacting proteins mammalian STE20-like protein kinases 3 and 4 (MST3 and MST4; also known as STK24 and STK26, respectively). Binding of active RHO proteins to FAM65A does not affect the kinase activity of MSTs but results in their relocation from the Golgi in a CCM3-dependent manner. This relocation is crucial for reorientation of the Golgi towards the leading edge and subsequent directional cell migration. Our results reveal a previously unidentified pathway downstream of RHO that regulates the polarity of migrating cells through Golgi reorientation in a FAM65A-, CCM3-and MST3-and MST4-dependent manner.

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Cerebral cavernous malformation proteins at a glance

Cited by 89 publications

References 88 publications

Endothelial fluid shear stress sensing in vascular health and disease

Endothelial fluid shear stress sensing in vascular health and disease

Nuclear Localization of Integrin Cytoplasmic Domain-associated Protein-1 (ICAP1) Influences β1 Integrin Activation and Recruits Krev/Interaction Trapped-1 (KRIT1) to the Nucleus

RHO binding to FAM65A regulates Golgi reorientation during cell migration

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