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Literature DB >> 17993501

Role of cyclic strain frequency in regulating the alignment of vascular smooth muscle cells in vitro.

Bo Liu¹, Ming-Juan Qu, Kai-Rong Qin, He Li, Zhen-Kun Li, Bao-Rong Shen, Zong-Lai Jiang.

Abstract

The arterial system is subjected to cyclic strain because of periodic alterations in blood pressure, but the effects of frequency of cyclic strain on arterial smooth muscle cells (SMCs) remain unclear. Here, we investigated the potential role of the cyclic strain frequency in regulating SMC alignment using an in vitro model. Aortic SMCs were subject to cyclic strain at one elongation but at various frequencies using a Flexercell Tension Plus system. It was found that the angle information entropy, the activation of integrin-beta1, p38 MAPK, and F/G actin ratio of filaments were all changed in a frequency-dependent manner, which was consistent with SMC alignment under cyclic strain with various frequencies. A treatment with anti-integrin-beta1 antibody, SB202190, or cytochalasin D inhibited the cyclic strain frequency-dependent SMC alignment. These observations suggested that the frequency of cyclic strain plays a role in regulating the alignment of vascular SMCs in an intact actin filament-dependent manner, and cyclic strain at 1.25 Hz was the most effective frequency influencing SMC alignment. Furthermore, integrin-beta1 and p38 MAPK possibly mediated cyclic strain frequency-dependent SMC alignment.

Entities: Chemical Gene

Mesh：

Year: 2007 PMID： 17993501 PMCID： PMC2212694 DOI： 10.1529/biophysj.106.098574

Source DB: PubMed Journal: Biophys J ISSN： 0006-3495 Impact factor: 4.033

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Authors: K Kada; K Yasui; K Naruse; K Kamiya; I Kodama; J Toyama
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3. Dynamic mechanical conditioning of collagen-gel blood vessel constructs induces remodeling in vitro.

Authors: D Seliktar; R A Black; R P Vito; R M Nerem
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4. Collagen organization in the branching region of human brain arteries.

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5. Strain-responsive regions in the platelet-derived growth factor-A gene promoter.

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6. Strain activation of bovine aortic smooth muscle cell proliferation and alignment: study of strain dependency and the role of protein kinase A and C signaling pathways.

Authors: I Mills; C R Cohen; K Kamal; G Li; T Shin; W Du; B E Sumpio
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7. Leukotrienes and tyrosine phosphorylation mediate stretching-induced actin cytoskeletal remodeling in endothelial cells.

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10. Effects of disturbed flow on endothelial cells.

Authors: J J Chiu; D L Wang; S Chien; R Skalak; S Usami
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Review 7. The effect of mechanical strain on soft (cardiovascular) and hard (bone) tissues: common pathways for different biological outcomes.

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