Your search keyword '"Mattot, Virginie"' showing total 3 results

1. MAGP‐1 and fibronectin control EGFL7 functions by driving its deposition into distinct endothelial extracellular matrix locations.

Author

Villain, Gaëlle, Lelievre, Etienne, Broekelmann, Tom, Gayet, Odile, Havet, Chantal, Werkmeister, Elisabeth, Mecham, Robert, Dusetti, Nelson, Soncin, Fabrice, and Mattot, Virginie

Subjects

EXTRACELLULAR matrix, FIBRONECTINS, LYSYL oxidase, ENDOTHELIAL cells, GENETIC regulation, CELL proliferation

Abstract

The extracellular matrix (ECM) is essential to provide mechanical support to tissues but is also a bioactive edifice which controls cell behavior. Cell signaling generated by ECM components through integrin‐mediated contacts, modulates cell biological activity. In addition, by sequestrating or releasing growth factors, the ECM is an active player of physiological and pathological processes such as vascular development. EGFL7 is mainly expressed during blood vessel development and is deposited in the ECM after secretion by endothelial cells. While EGFL7 is known to control various endothelial cell molecular mechanisms [i.e., the repression of endothelial‐derived lysyl oxidase (LOX) enzyme, the regulation of the Notch pathway, and the expression of leukocyte adhesion molecules and of RHOA by endothelial cells], it is not established whether EGFL7 functions when bound to the ECM. Here, we show that microfibrillar‐associated glycoprotein‐1 (MAGP‐1) and fibronectin drive the deposition of EGFL7 into both fibers and individual aggregates in endothelial ECM. Although EGFL7 does not need to be docked into the ECM to control endothelial adhesion molecule expression, the ECM accumulation of EGFL7 is required for its regulation of LOX activity and of HEY2 expression along the Notch pathway. The interaction of EGFL7 with MAGP‐1 is necessary for LOX activity repression by EGFL7 while it does not participate in the control of the Notch pathway by this protein. Altogether, this study highlights the roles played by EGFL7 in controlling various endothelial molecular mechanisms upon its localization and shows how the ECM can modulate its functions. EGFL7 is a secreted protein mainly expressed by endothelial cells during angiogenesis and deposited in the extracellular matrix (ECM) through poorly understood molecular mechanisms. We report that EGFL7 is deposited either in thick fibers associated with microfibrillar‐associated glycoprotein‐1 (MAGP‐1) or as aggregates through its interaction with fibronectin in the human umbilical vein endothelial cells ECM. EGFL7 regulates lysyl oxidase activity when associated with MAGP‐1; it must be deposited in the ECM to partially control the Notch pathway, while it represses endothelial cell activation independently of its accumulation in the ECM. [ABSTRACT FROM AUTHOR]

Published

2018

2. Vasopressin Synthesis by the Magnocellular Neurons is Different in the Supraoptic Nucleus and in the Paraventricular Nucleus in Human and Experimental Septic Shock.

Author

Sonneville, Romain, Guidoux, Céline, Barrett, Lucinda, Viltart, Odile, Mattot, Virginie, Polito, Andrea, Siami, Shidasp, de la Grandmaison, Geoffroy Lorin, Blanchard, Anne, Singer, Mervyn, Annane, Djillali, Gray, Françoise, Brouland, Jean-Philippe, and Sharshar, Tarek

Subjects

VASOPRESSIN, SUPRAOPTIC nucleus, SEPTIC shock, NEUROHYPOPHYSIS, AMINO acids, MESSENGER RNA, THERAPEUTICS

Abstract

Impaired arginine vasopressin (AVP) synthesis and release by the neurohypophyseal system, which includes the neurohypophysis and magnocellular neurons of the paraventricular and supraoptic nuclei, have been postulated in septic shock, but changes in this system have never been assessed in human septic shock, and only partially experimentally. We investigated AVP synthesis and release by the neurohypophyseal system in 9 patients who died from septic shock and 10 controls, and in 20 rats with fecal peritonitis-induced sepsis and 8 sham-operation controls. Ten rats died spontaneously from septic shock, and the others were sacrificed. In patients with septic shock, as in rats that died spontaneously following sepsis induction, AVP immunohistochemical expression was decreased in the neurohypophysis and supraoptic magnocellular neurons, whereas it was increased in the paraventricular magnocellular neurons. No significant change was observed in AVP messenger RiboNucleic Acid (mRNA) expression assessed by in situ hybridization in either paraventricular or supraoptic magnocellular cells. This study shows that both in human and experimental septic shock, AVP posttranscriptional synthesis and transport are differently modified in the magnocellular neurons of the supraoptic and paraventricular nuclei. This may account for the inappropriate AVP release in septic shock and suggests that distinct pathogenic mechanisms operate in these nuclei. [ABSTRACT FROM AUTHOR]

Published

2010

3. VE-statin/egfl7 regulates vascular elastogenesis by interacting with lysyl oxidases.

Author

Lelièvre, Etienne, Hinek, Aleksander, Lupu, Florea, Buquet, Christelle, Soncin, Fabrice, and Mattot, Virginie

Subjects

PROTEINS, ENDOTHELIAL seeding, EXTRACELLULAR matrix proteins, GLYCOPROTEINS, CELL migration, ENZYMES

Abstract

We previously characterized VE-statin/egfl7, a protein that is exclusively secreted by endothelial cells and modulates smooth muscle cell migration. Here, we show that VE-statin/egfl7 is the first known natural negative regulator of vascular elastogenesis. Transgenic mice, expressing VE-statin/egfl7 under the control of keratin-14 promoter, showed an accumulation of VE-statin/egfl7 in arterial walls where its presence correlated with an impaired organization of elastic fibres. In vitro, fibroblasts cultured in the presence of VE-statin/egfl7 were unable to deposit elastic fibres due to a deficient conversion of soluble tropoelastin into insoluble mature elastin. VE-statin/egfl7 interacts with the catalytic domain of lysyl oxidase (LOX) enzymes and, in endothelial cells, endogenous VE-statin/egfl7 colocalizes with LoxL2 and inhibits elastic fibre deposition. In contrast, mature elastic fibres are abundantly deposited by endothelial cells that are prevented from producing endogenous VE-statin/egfl7. We propose a model where VE-statin/egfl7 produced by endothelial cells binds to the catalytic domains of enzymes of the LOX family in the vascular wall, thereby preventing the crosslink of tropoelastin molecules into mature elastin polymers and regulating vascular elastogenesis. [ABSTRACT FROM AUTHOR]

Published

2008