Propagation of fast and slow intercellular Ca2+ waves in primary cultured arterial smooth muscle cells

Jean-Louis Bény, Nadia Halidi, Jean-Jacques Meister
2011
Article

Résumé

Smooth muscle contraction is regulated by changes in cytosolic Ca2+ concentration (Ca2+). In response to stimulation, Ca2+ increase in a single cell can propagate to neighbouring cells through gap junctions, as intercellular Ca2+ waves. To investigate the mechanisms underlying Ca2+ wave propagation between smooth muscle cells, we used primary cultured rat mesenteric smooth muscle cells (pSMCs). Cells were aligned with the microcontact printing technique and a single pSMC was locally stimulated by mechanical stimulation or by microejection of KCl. Mechanical stimulation evoked two distinct Ca2+ waves: (1) a fast wave (2 mm/s) that propagated to all neighbouring cells, and (2) a slow wave (20 mu m/s) that was spatially limited in propagation. KCl induced only fast Ca2+ waves of the same velocity as the mechanically induced fast waves. Inhibition of gap junctions, voltage-operated calcium channels, inositol 1,4,5-trisphosphate (IP3) and ryanodine receptors, shows that the fast wave was due to gap junction mediated membrane depolarization and subsequent Ca2+ influx through voltage-operated Ca2+ channels, whereas, the slow wave was due to Ca2+ release primarily through IP3 receptors. Altogether, these results indicate that temporally and spatially distinct mechanisms allow intercellular communication between SMCs. In intact arteries this may allow fine tuning of vessel tone. (C) 2011 Elsevier Ltd. All rights reserved.

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Jean-Louis Bény, Nadia Halidi, Jean-Jacques Meister
2011
Article

Résumé

Official source

https://infoscience.epfl.ch/record/170700?ln=fr

À propos de ce résultat

Concepts associés (8)

Concepts associés

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Publications associées (19)

Publications associées

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Tissue blood flow is controlled by changes in the diameter of the arteries and arterioles through coordinated contraction and relaxation of smooth muscle cells (SMCs) within the vascular wall. The contraction of SMCs is primarily regulated by the intracellular Ca2+ concentration ([Ca2+]i). An increase in [Ca2+]i, in response to stimuli, can propagate from cell to cell, as an intercellular Ca2+ wave along the vessel wall and can activate the process of contraction. The aim of this thesis is to elucidate the mechanisms underlying intercellular Ca2+ wave propagation between SMCs. In the first part of this thesis, we used A7r5 cells, a rat aortic SMC line, loaded with the fluorescent Ca2+ dye Fluo-4 to study intercellular Ca2+ wave propagation. Local mechanical stimulation evoked a Ca2+ wave in the stimulated cell that failed to propagate to neighboring cells. Using primary cultured rat mesenteric smooth muscle cells (pSMCs) instead, intercellular Ca2+ wave propagation was observed. To understand the difference in junctional communication between A7r5 and pSMCs, we investigated the expression of connexin37 (Cx37), Cx40, Cx43 and Cx45. RNA and protein analysis demonstrated that Cx40 – in contrast to A7r5 cells – is not expressed in pSMCs. To confirm that coexpression of Cx40 and Cx43 interfered with junctional communication, we used 6B5N cells, a clone of A7r5 cells with a higher Cx43:Cx40 expression ratio. Junctional communication, assessed by transfer of Lucifer Yellow and propagation of Ca2+ waves, was comparable between 6B5N cells and pSMCs. In addition, Ca2+ wave propagation was inhibited with the connexin-mimetic peptide 43Gap 26, that targets Cx43. Our results demonstrate that Cx43 gap junctions are primarily involved in mediating intercellular Ca2+ waves between pSMCs, and the coexpression of Cx43 with Cx40 may interfere with Cx43 gap junction formation, affecting cell-cell communication. In the second part of this thesis, we applied the microcontact printing technique to culture pSMCs on collagen lines. The aligned arrangement of the cells facilitates the observation of Ca2+ wave progression from one cell to another. To induce a Ca2+ wave, a single pSMC was locally stimulated with a micropipette (transientmechanical stimulation) or by microejection of KCl. Mechanical stimulation evoked two distinct Ca2+ waves: 1) a fast wave (∼2 mm/s) that propagated to all observed neighbouring cells, and 2) a slow wave (∼20 µm/s), that was most often limited in propagation to the first cell. KCl induced only fast Ca2+ waves of the same velocity as the mechanically-induced fast waves. Inhibition of gap junctions, voltage-operated calcium channels, inositol 1,4,5-trisphosphate (IP3) and ryanodine receptors, showed that the fast wave was due to gap junction mediated membrane depolarization and subsequent Ca2+ influx, whereas, the slow wave was due to Ca2+ release primarily through IP3 receptors. Together, these results suggest a mechanism by which intercellular Ca2+ waves can propagate between SMCs of the arterial wall.

EPFL2011

Chargement

Coordination of Myofibroblast Contraction in Vitro

Lysianne Follonier Castella

The aim of this thesis is to elucidate the common mechanisms that regulate myofibroblast contraction and intercellular communication, with a particular focus on the role of Ca2+ signalling. Synthesis and remodelling of collagenous matrix by myofibroblasts are key elements in the healing process of injured organs. Deregulation of myofibroblast activity and excessive remodelling result in hypertrophic scarring and organ fibrosis. Myofibroblasts are specialised fibroblasts with particularly contractile stress fibres and features that resemble smooth muscle cells. Although myofibroblast contraction is acknowledged being responsible for wound closure and tissue contracture, the underlying regulation mechanisms are unclear. In particular, it remains elusive to what extent changes in the cytosolic Ca2+, a central regulator of smooth muscle contraction, regulate myofibroblast activities. Previous studies have revealed that cultured fibroblasts and myofibroblasts exhibit spontaneous cytosolic Ca2+ oscillations but a link with cell contraction has not been established. In the first part of this thesis, we are testing the hypothesis that cytosolic Ca2+ oscillations regulate myofibroblast contraction. For this, we use analysis of Ca2+ dynamics with fluorescent indicators, tracking of stress-fibre-linked microbeads on the myofibroblast surface and quantification of subcellular pulling events with atomic force microscopy. This combined approach demonstrates that myofibroblasts exhibit periodic (∼100 seconds) Ca2+ oscillations that control small (∼400 nm) and weak (∼100 pN) contractions. Using deformable culture substrate to assess cell isometric tension, we further demonstrate that myofibroblast contraction is regulated at two levels: variations of intracellular Ca2+ mediate contractions of dorsal stress fibres whereas the Ca2+-independent Rho kinase pathway is responsible for maintaining overall isometric cell tension. In the second part of this thesis, we investigate whether the observed subcellular contractions and Ca2+ oscillations may play a role in coordinating the activities between directly contacting myofibroblasts. Rational for this hypothesis is that myofibroblasts in densely populated wound granulation tissue form two types of intercellular junctions: adherens junctions that mechanically couple stress fibres between cells, and gap junctions that provide electrochemical coupling. Both junctions have been shown to play a role in modulating the contraction of wound tissue and of myofibroblast collagen gel cultures but their precise roles are still elusive. To fill this gap in knowledge, we analyse the coordination of Ca2+ oscillations between adjacent fibroblasts and myofibroblasts, respectively. Intercellular communication is modulated with pharmacological treatments acting on either mechanical or electrochemical coupling, as well as on the cell's contractile apparatus and mechanosensitive membrane channels. Our results demonstrate that stress-fibre associated adherens junctions mechanically coordinate myofibroblast activities within a cell population. This mechanism implies that the transmission of contractile events from one cell induces a Ca2+ influx through mechanosensitive ion channels in its neighbour and there triggers a new contraction. Based on these results we suggest that, at the tissue level, myofibroblasts remodel collagen by Ca2+-dependent micro-contractile events that add up to macroscopic tissue contracture, whereas Rho kinase maintains cell isometric tension. Mechanical coupling via adherens junctions may simultaneously improve the remodelling of cell-dense tissue by coordinating the activity of myofibroblasts.

EPFL2010

Chargement

Emergent properties of electrically coupled smooth muscle cells

Michèle Koenigsberger, Jean-Jacques Meister, Roger Sauser

Asynchronous and synchronous calcium oscillations occur in a variety of cells. A well-established pathway for intercellular communication is provided by gap junctions which connect adjacent cells and can mediate electrical and chemical coupling. Several experimental studies report that cells presenting only a transient increase when freshly dispersed may oscillate when they are coupled. Such observations suggest that the role of gap junctions is not only to coordinate calcium oscillations of adjacent cells. Gap junctions may also be important to generate oscillations. Here we illustrate the emergent properties of electrically coupled smooth muscle cells using a model that we recently proposed. A bifurcation analysis in the case of two cells reveals that synchronous and asynchronous calcium oscillations can be induced by electrical coupling. In a larger population of smooth muscle cells, electrical coupling may result in the creation of groups of cells presenting synchronous calcium oscillations. The elements of one group may be distant from each other. Moreover, our results highlight a general mechanism by which gap junctional electrical coupling can give rise to out of phase calcium oscillations in smooth muscle cells that are non-oscillating when uncoupled. All these observations remain true in the case of non-identical cells, except that the solution corresponding to synchronous calcium oscillations disappears and that the formation of groups is sensitive to the degree of heterogeneity. © 2005 Society for Mathematical Biology. Published by Elsevier Ltd. All rights reserved.

Springer-Verlag2005

Chargement

EPFL2011

Coordination of Myofibroblast Contraction in Vitro

Lysianne Follonier Castella

EPFL2010