Organs and tissues adapt to acute or chronic mechanical stress by remodeling their actin cytoskeletons. Cells that are stimulated by cyclic stretch or shear stress in vitro undergo bimodal cytoskeletal responses that include rapid reinforcement and gradual reorientation of actin stress fibers; however, the mechanism by which cells respond to mechanical cues has been obscure. We report that the application of either unidirectional cyclic stretch or shear stress to cells results in robust mobilization of zyxin from focal adhesions to actin filaments, whereas many other focal adhesion proteins and zyxin family members remain at focal adhesions. Mechanical stress also induces the rapid zyxin-dependent mobilization of vasodilator-stimulated phosphoprotein from focal adhesions to actin filaments. Thickening of actin stress fibers reflects a cellular adaptation to mechanical stress; this cytoskeletal reinforcement coincides with zyxin mobilization and is abrogated in zyxin-null cells. Our findings identify zyxin as a mechanosensitive protein and provide mechanistic insight into how cells respond to mechanical cues.
Focal adhesions are specialized regions of the cell surface where integrin receptors and associated proteins link the extracellular matrix to the actin cytoskeleton. To define the cellular role of the focal adhesion protein zyxin, we characterized the phenotype of fibroblasts in which the zyxin gene was deleted by homologous recombination. Zyxin-null fibroblasts display enhanced integrin-dependent adhesion and are more migratory than wild-type fibroblasts, displaying reduced dependence on extracellular matrix cues. We identified differences in the profiles of 75- and 80-kD tyrosine-phosphorylated proteins in the zyxin-null cells. Tandem array mass spectrometry identified both modified proteins as isoforms of the actomyosin regulator caldesmon, a protein known to influence contractility, stress fiber formation, and motility. Zyxin-null fibroblasts also show deficits in actin stress fiber remodeling and exhibit changes in the molecular composition of focal adhesions, most notably by severely reduced accumulation of Ena/VASP proteins. We postulate that zyxin cooperates with Ena/VASP proteins and caldesmon to influence integrin-dependent cell motility and actin stress fiber remodeling.
Mechanical stimulation induces zyxin-dependent actin cytoskeletal reinforcement. Stretch induces MAPK activation, zyxin phosphorylation, and recruitment to actin stress fibers, independent of p130Cas. Zyxin's C-terminal LIM domains are required for stretch-induced targeting to stress fibers, and zyxin's N-terminus is necessary for actin remodeling.
Background: Reorientation of the cell axis induced by cyclic stretching is an early response to mechanical forces in vitro. However, quantitative assay for this phenomenon has been difficult due to lack of robust methods. We hypothesized that cell orientation may be redefined by the orientation of actin fibers. We developed image processing methods to quantitate the orientation and density of actin fibers. Methods: A convolution filter using Sobel kernels was adapted to determine the orientation and density of actin fibers in human endothelial cells. Unidirectional stretching (10%, 0.5 Hz) was applied to induce cytoskeletal remodeling by varying the duration of stimulation (control, 0.5, 1, 2, 5, 10, and 20 h). Actin fibers were visualized by fluorescent phalloidin. The image processing method was compared with the manual method for reproducibility. Both confluent and subconfluent cells were tested to assess the efficacy of the methods.
Mechanical force induces protein phosphorylations, subcellular redistributions, and actin remodeling. We show that mechanical activation of the p38 MAPK pathway leads to phosphorylation of HspB1 (hsp25/27), which redistributes to cytoskeletal structures, and contributes to the actin cytoskeletal remodeling induced by mechanical stimulation.
Embryonic cardiovascular function has been extensively studied in vivo in the chick embryo. However, the geometry of mammalian and avian hearts differs; the mammalian cardiovascular system is coupled to both yolk sac and placental circulations, and unique murine genetic models associated with structural and functional cardiovascular defects are now available. We therefore adapted techniques validated for the chick embryo to define cardiovascular dimensions and function in the mouse embryo. We bred C3HeB female and C57B1/J6 male mice and ICR pairs for experiments on embryonic days (EDs) 10.5 to 14.5 (n = 130 dams). After maternal anesthesia (pentobarbital, 60 mg/kg IP), laparotomy, and sequential regional hysterotomy, we exposed and then imaged individual embryos at 60 Hz (video) in the ventral and/or left anterior oblique views while maintaining uteroplacental continuity. We measured epicardial chamber dimensions and then calculated right and left ventricular elliptical volumes from ares. In addition, we measured pulsed-Doppler blood velocity across the atrioventricular cushions and ventricular outflow tract. We maintained embryonic temperature with a heated surgical platform, topical oxygenated and warmed buffer, and warming lamps. Embryonic heart rate increased from 124.7 +/- 5.2 to 194.3 +/- 13.2 bpm from EDs 10.5 to 14.5 (P < .01). Right and left ventricular end-diastolic and end-systolic dimensions increased (P < .05 by ANOVA for each). Maximal ventricular mean inflow and outflow velocities increased from 62.33 +/- 4.06 to 106.23 +/- 11.59 and from 55.79 +/- 6.11 to 91.61 +/- 6.93 mm/s, respectively (P < .05 by ANOVA for each). Thus, as has been done for chick and rat embryos, the maturation of murine embryonic cardiovascular function can be quantified in vivo, setting the stage for the investigation of structure-function relations in mouse models of cardiovascular development and disease.
Filopodia formation is positively regulated by β3 integrin–EGFR cross-talk, which regulates p190RhoGAP activity and localization in normal mouse mammary gland epithelial cells.
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