Emmanuelle Planus

Assessment of Mechanical Properties of Adherent Living Cells by Bead Micromanipulation: Comparison of Magnetic Twisting Cytometry vs Optical Tweezers

We compare the measurements of viscoelastic properties of adherent alveolar epithelial cells by two micromanipulation techniques: (i) magnetic twisting cytometry and (ii) optical tweezers, using microbeads of same size and similarly attached to F-actin. The values of equivalent Young modulus E, derived from linear viscoelasticity theory, become consistent when the degree of bead immersion in the cell is taken into account. E-values are smaller in (i) than in (ii): approximately 34-58 Pa vs approximately 29-258 Pa, probably because higher stress in (i) reinforces nonlinearity and cellular plasticity. Otherwise, similar relaxation time constants, around 2 s, suggest similar dissipative mechanisms.

Keratinocyte growth factor promotes cell motility during alveolar epithelial repair in vitro

Epithelia play a key role as protective barriers, and mechanisms of repair are crucial for restoring epithelial barrier integrity, especially in the lung. Cell spreading and migration are the first steps of reepithelialization. Keratinocyte growth factor (KGF) plays a key role in lung epithelial repair and protects against various injuries. We hypothesized that KGF may protect the lung not only by inducing proliferation but also by promoting epithelial repair via enhanced epithelial cell migration. In an in vitro wound-healing model, we found that KGF enhanced wound closure by 33%. KGF acted primarily by inducing lamellipodia emission (73.2 +/- 3.9% of KGF-treated cells had lamellipodia vs 61.3 +/- 3.4% of control cells) and increasing their relative surface area (59 +/- 2.7% with KGF vs 48 +/- 2.0% in controls). KGF reduced cytoskeleton stiffness as measured by magnetic twisting cytometry and increased cell motility (5.8 +/- 0.42 microm/h with KGF vs 3.7 +/- 0.41 microm/h in controls). KGF-increased cell motility was associated with increased fibronectin deposition during wound closure and with fibronectin reorganization into fibrils at the rear of the cells. Taken together, our findings strongly suggest that KGF may promote epithelial repair through several mechanisms involved in cell migration.

Partitioning of Cortical and Deep Cytoskeleton Responses from Transient Magnetic Bead Twisting

AbstractWe attempted to estimate in living adherent epithelial alveolar cells, the degree of structural and mechanical heterogeneity by considering two individualized cytoskeleton components, i.e., a submembranous “cortical” cytoskeleton and a “deep” cytoskeleton (CSK). F-actin structure characterizing each CSK component was visualized from spatial reconstructions at low and high density, respectively, especially in a 10-μm-cubic neighborhood including the bead. Specific mechanical properties (Young elastic and viscous modulus E and η) were revealed after partitioning the magnetic twisting cytometry response using a double viscoelastic “solid” model with asymmetric plastic relaxation. Results show that the cortical CSK response is a faster (τ 1≤ 0.7s), softer (E1: 63-109 Pa), moderately viscous (η1: 7-18 Pa s), slightly tensed, and easily damaged structure compared to the deep CSK structure which appears slower (τ2 ∼ n

Prestress and adhesion site dynamics control cell sensitivity to extracellular stiffness.

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Tensegrity behaviour of cortical and cytosolic cytoskeletal components in twisted living adherent cells

n min), stiffer (E2: 95-204 Pa), highly viscous (η2: 760-1967 Pa s), more tensed, and fully elastic, while exhibiting a larger stress hardening behavior. Adding drug depolymerizing actin filaments decreased predominantly the deep CSK stiffness. By contrast, an agent altering cell–matrix interactions affected essentially the cortical CSK stiffness. We concluded that partitioning the CSK within cortical and deep structures is largely consistent with their respective functional activities.

Time course of actin cytoskeleton stiffness and matrix adhesion molecules in human bronchial epithelial cell cultures.

An original homogenization method was used to analyze the nonlinear elastic properties of epithelial cells probed by magnetic twisting cytometry. In this approach, the apparent rigidity of a cell with nonlinear mechanical properties is deduced from the mechanical response of the entire population of adherent cells. The proposed hyperelastic cell model successfully accounts for the variability in probe-cell geometrical features, and the influence of the cell-substrate adhesion. Spatially distributed local secant elastic moduli had amplitudes ranging from 10 to 400 Pa. The nonlinear elastic behavior of cells may contribute to the wide differences in published results regarding cell elasticity moduli.

Sensitivity of alveolar macrophages to substrate mechanical and adhesive properties

This study aims at improving the understanding of mechanisms responsible for cell sensitivity to extracellular environment. We explain how substrate mechanical properties can modulate the force regulation of cell sensitive elements primarily adhesion sites. We present a theoretical and experimental comparison between two radically different approaches of the force regulation of adhesion sites that depends on their either stationary or dynamic behavior. The most classical stationary model fails to predict cell sensitivity to substrate stiffness whereas the dynamic model predicts extracellular stiffness dependence. This is due to a time dependent reaction force in response to actomyosin traction force exerted on cell sensitive elements. We purposely used two cellular models, i.e., alveolar epithelial cells and alveolar macrophages exhibiting respectively stationary and dynamic adhesion sites, and compared their sensitivity to theoretical predictions. Mechanical and structural results show that alveolar epithelial cells exhibit significant prestress supported by evident stress fibers and lacks sensitivity to substrate stiffness. On the other hand, alveolar macrophages exhibit low prestress and exhibit sensitivity to substrate stiffness. Altogether, theory and experiments consistently show that adhesion site dynamics and cytoskeleton prestress control cell sensitivity to extracellular environment with an optimal sensitivity expected in the intermediate range.

Effect of doxycycline on sulfur mustard-induced respiratory lesions in guinea pigs

Respiratory tract lesions induced by sulfur mustard (SM), a chemical warfare agent, are characterized by epithelial damage associated with inflammatory cell infiltration. To test the potential role of matrix metalloproteinase gelatinases in these lesions, we evaluated gelatinase activity, albumin content, and total cell count in bronchoalveolar lavage fluid of guinea pigs 24 h after an intratracheal injection of 0.2 mg/kg of SM. The bronchial lavage and alveolar lavage fluids were analyzed separately. The increase in inflammatory cell content of the bronchial lavage fluid, mainly macrophages, observed in SM-intoxicated guinea pigs was accompanied by an increase in albumin and in 92-kDa gelatinase activity. There was a significant correlation between albumin content and 92-kDa gelatinase activity (r = 0.67) and between 92-kDa gelatinase and the number of macrophages. Immunohistochemistry performed on tracheal sections showed the presence of 92-kDa gelatinase at the site of intraepithelial cleavages. Zymography analysis of culture medium conditioned by guinea pig tracheal epithelial cells demonstrated that these cells produced in vitro 92-kDa gelatinase on stimulation. Culture of human bronchial epithelial cells obtained by the explant technique showed a marked increase in 92-kDa gelatinase after exposure to 5 x 10(-5) M SM that reinforced the relevance of our animal results to human exposure to SM. These results suggest that in SM respiratory intoxication, 92-kDa gelatinase of both inflammatory and epithelial cell origins could be involved in epithelial cell detachment.