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Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts

We investigated the cellular mechanisms underlying force generation and matrix contraction, using human corneal, Tenon's and scleral fibroblasts in a standard collagen matrix. We used timelapse light and confocal reflection microscopy to analyse concomitantly cell behaviour and matrix remodelin...

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Detalles Bibliográficos
Autores principales: Dahlmann-Noor, Annegret H., Martin-Martin, Belen, Eastwood, Mark, Khaw, Peng T., Bailly, Maryse
Formato: Texto
Lenguaje:English
Publicado: Academic Press 2007
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2764386/
https://www.ncbi.nlm.nih.gov/pubmed/17869245
http://dx.doi.org/10.1016/j.yexcr.2007.07.040
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author Dahlmann-Noor, Annegret H.
Martin-Martin, Belen
Eastwood, Mark
Khaw, Peng T.
Bailly, Maryse
author_facet Dahlmann-Noor, Annegret H.
Martin-Martin, Belen
Eastwood, Mark
Khaw, Peng T.
Bailly, Maryse
author_sort Dahlmann-Noor, Annegret H.
collection PubMed
description We investigated the cellular mechanisms underlying force generation and matrix contraction, using human corneal, Tenon's and scleral fibroblasts in a standard collagen matrix. We used timelapse light and confocal reflection microscopy to analyse concomitantly cell behaviour and matrix remodeling during contraction and devised a novel index to quantify dynamic cell behaviour in 3D. Based on the previously described culture force monitor, a novel simultaneous imaging and micro-culture force monitor system (SIM–CFM) was developed to measure the mechanical strain generated during matrix contraction whilst simultaneously recording cell and matrix behaviour. Ocular fibroblasts show marked differences in macroscopic matrix contraction profiles, with corneal fibroblasts inducing the strongest, and scleral the weakest, contraction. We identified four factors that determine the early matrix contraction profile: 1) cell size, 2) intrinsic cellular force, 3) dynamic cell protrusive activity and 4) net pericellular matrix displacement. Intrinsic cellular force and dynamic activity appear to be independent unique characteristics of each cell type and might serve as predictors of matrix contraction. The identification of these factors raises the fundamental new possibilities of predicting the ability of tissues to contract and scar and of modulating tissue contraction by targeting intracellular pathways linked to protrusive activity and force generation.
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spelling pubmed-27643862009-10-23 Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts Dahlmann-Noor, Annegret H. Martin-Martin, Belen Eastwood, Mark Khaw, Peng T. Bailly, Maryse Exp Cell Res Research Article We investigated the cellular mechanisms underlying force generation and matrix contraction, using human corneal, Tenon's and scleral fibroblasts in a standard collagen matrix. We used timelapse light and confocal reflection microscopy to analyse concomitantly cell behaviour and matrix remodeling during contraction and devised a novel index to quantify dynamic cell behaviour in 3D. Based on the previously described culture force monitor, a novel simultaneous imaging and micro-culture force monitor system (SIM–CFM) was developed to measure the mechanical strain generated during matrix contraction whilst simultaneously recording cell and matrix behaviour. Ocular fibroblasts show marked differences in macroscopic matrix contraction profiles, with corneal fibroblasts inducing the strongest, and scleral the weakest, contraction. We identified four factors that determine the early matrix contraction profile: 1) cell size, 2) intrinsic cellular force, 3) dynamic cell protrusive activity and 4) net pericellular matrix displacement. Intrinsic cellular force and dynamic activity appear to be independent unique characteristics of each cell type and might serve as predictors of matrix contraction. The identification of these factors raises the fundamental new possibilities of predicting the ability of tissues to contract and scar and of modulating tissue contraction by targeting intracellular pathways linked to protrusive activity and force generation. Academic Press 2007-12-10 /pmc/articles/PMC2764386/ /pubmed/17869245 http://dx.doi.org/10.1016/j.yexcr.2007.07.040 Text en © 2007 Elsevier Inc. https://creativecommons.org/licenses/by/3.0/ Open Access under CC BY 3.0 (https://creativecommons.org/licenses/by/3.0/) license
spellingShingle Research Article
Dahlmann-Noor, Annegret H.
Martin-Martin, Belen
Eastwood, Mark
Khaw, Peng T.
Bailly, Maryse
Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
title Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
title_full Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
title_fullStr Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
title_full_unstemmed Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
title_short Dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
title_sort dynamic protrusive cell behaviour generates force and drives early matrix contraction by fibroblasts
topic Research Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC2764386/
https://www.ncbi.nlm.nih.gov/pubmed/17869245
http://dx.doi.org/10.1016/j.yexcr.2007.07.040
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