Jean-Marie Daniel Lamazière scite author profile

Abstract-Recent studies have shown that large-artery wall remodeling per se does not reduce distensibility in hypertension, indicating qualitative or quantitative changes in arterial components. The aim of the study was to determine in 1-year-old spontaneously hypertensive rats (SHRs) the changes in the elastic properties of large arteries, as assessed by the incremental elastic modulus (E inc ), and the changes in the extracellular matrix, including fibronectin (FN) and ␣5␤1-integrin. The relationship between E inc and circumferential wall stress was calculated from in vivo pulsatile changes in blood pressure and arterial diameter by using a high-resolution echo-tracking system at the site of the abdominal aorta and in vitro medial cross-sectional area. E inc -stress curves and FN and integrin ␣5-subunit contents were determined for each animal. Mean stress and E inc were higher in SHRs than in Wistar rats. However, in a common range of stress, E inc -stress curves for SHRs were superimposable on those for Wistar rats, indicating that wall materials in both strains have equivalent mechanical behavior. Immunohistochemistry indicated that total FN, EIIIA FN isoform, and ␣5-integrin increased in the SHRs aortas without changes in elastin and collagen densities. Key Words: SHR Ⅲ elastic modulus Ⅲ aorta Ⅲ fibronectin Ⅲ ␣5␤1-integrin T he mechanical properties of large arteries play a major role in cardiovascular hemodynamics through the buffering of stroke volume and the propagation of the pressure pulse.1,2 It is well recognized that mechanical properties of large arteries are primarily determined by the composition of the arterial wall. The ECM proteins, mainly collagen and elastin, influence the "passive" mechanical properties of the arterial wall whereas its "active" properties depend on the activation of VSMCs.It was generally accepted that hypertension produced an increase in large-artery stiffness.1-4 However, recent studies have shown that arterial stiffness is not increased, despite wall hypertrophy, in either hypertensive patients or SHRs. [5][6][7][8][9] This finding suggests that sustained hypertension is associated with a rearrangement of the arterial wall material, implying qualitative or quantitative changes in arterial components leading to the mechanical adaptation of the arterial wall.The elastic properties of the arterial wall material depend not only on the SMC, elastin, and collagen contents but also on the way these components are spatially organized within the media. 3,10,11 Through an interaction with specific cellular integrin receptors, FN plays an important role in cell-matrix interactions. In addition, FN may also influence VSMC phenotype.12-14 The present study was undertaken to relate the changes in the elastic properties of the arterial wall material to its composition in the ECM and to focus on FN and its specific receptor, the ␣5␤1-integrin.The interaction of specific ECM proteins with their integrin receptors has been shown to play a central role in transmitting mechanical forces to...

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Thrombocytopenia resulting from mutations in filamin A can be expressed as an isolated syndrome

Nurden

et al. 2011

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Hypoxia Preconditioned Mesenchymal Stem Cells Improve Vascular and Skeletal Muscle Fiber Regeneration After Ischemia Through a Wnt4-dependent Pathway

et al. 2010

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Mesenchymal stem cells (MSC) are multipotent postnatal stem cells, involved in the treatment of ischemic vascular diseases. We investigate the ability of MSC, exposed to short-term hypoxic conditions, to participate in vascular and tissue regeneration in an in vivo model of hindlimb ischemia. Transplantation of hypoxic preconditioned murine MSC (HypMSC) enhanced skeletal muscle regeneration at day 7, improved blood flow and vascular formation compared to injected nonpreconditioned MSC (NormMSC). These observed effects were correlated with an increase in HypMSC engraftment and a putative role in necrotic skeletal muscle fiber clearance. Moreover, HypMSC transplantation resulted in a large increase in Wnt4 (wingless-related MMTV integration site 4) expression and we demonstrate its functional significance on MSC proliferation and migration, endothelial cell (EC) migration, as well as myoblast differentiation. Furthermore, suppression of Wnt4 expression in HypMSC, abrogated the hypoxia-induced vascular regenerative properties of these cells in the mouse hindlimb ischemia model. Our data suggest that hypoxic preconditioning plays a critical role in the functional capabilities of MSC, shifting MSC location in situ to enhance ischemic tissue recovery, facilitating vascular cell mobilization, and skeletal muscle fiber regeneration via a paracrine Wnt-dependent mechanism.

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Frizzled 4 Regulates Arterial Network Organization Through Noncanonical Wnt/Planar Cell Polarity Signaling

Descamps

Sewduth

Tojais

et al. 2012

Circulation Research

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Rationale: A growing body of evidence supports the hypothesis that the Wnt/planar cell polarity (PCP) pathway regulates endothelial cell proliferation and angiogenesis, but the components that mediate this regulation remain elusive.Objective: We investigated the involvement of one of the receptors, Frizzled4 (Fzd4), in this process because its role has been implicated in retinal vascular development. Methods and Results:We found that loss of fzd4 function in mice results in a striking reduction and impairment of the distal small artery network in the heart and kidney. We report that loss of fzd4 decreases vascular cell proliferation and migration and decreases the ability of the endothelial cells to form tubes. We show that fzd4 deletion induces defects in the expression level of stable acetylated tubulin and in Golgi organization during migration. Deletion of fzd4 favors Wnt noncanonical AP1-dependent signaling, indicating that Fzd4 plays a pivotal role favoring PCP signaling. Our data further demonstrate that Fzd4 is predominantly localized on the top of the plasma membrane, where it preferentially induces Dvl3 relocalization to promote its activation and ␣-tubulin recruitment during migration. In a pathological mouse angiogenic model, deletion of fzd4 impairs the angiogenic response and leads to the formation of a disorganized arterial network. Key Words: blood vessels Ⅲ imaging Ⅲ ischemia Ⅲ transgenic mice Ⅲ vascular biology D uring development, blood vessel formation ensures tissue growth and organ function in the entire organism. The essential role of Wnt/Frizzled signaling in the development of the vascular network was established when it was demonstrated that deletion of distinct Wnt genes caused embryonic lethality with severe phenotypes. A growing body of evidence supports the hypothesis that the Wnt/planar cell polarity (PCP) pathway regulates endothelial cell proliferation and angiogenesis, 1-3 but the components that mediate this regulation remain elusive. Embryo-specific deletion of Wnt7b/7a, which bypassed early lethality because of Wnt7b effect on placenta formation, demonstrated a role of Wnt7a/7b ligands in blood-brain barrier formation through Wnt canonical signaling. 4 These models also indicated that Fzd4 is a prominent receptor involved in vascular formation. Fzd4 has been linked to genetic diseases altering retinal vascular development in Norrie disease, familial exudative vitreoretinopathy, 5,6 and osteoporosis-pseudoglioma. 7 In mice, Fzd4 controls retinal vascular growth and organization, 8 and blood-brain barrier formation in the cerebellum. 9 Moreover, Fzd4 is linked to sterility. 10 We have previously demonstrated that the action of sFRP1, a secreted regulator of the Wnt pathway, is mediated in part by Fzd4 in endothelial cells. 2 The sFRP1 stimulates angiogenesis in vivo and in vitro 11 via a noncanonical Wnt-dependent mechanism and activates downstream signaling factors such as GSK3␤ and Rac1. There is growing evidence of a link between noncanonical Wnt/PCP signaling and angi...

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