The effect of substrate microtopography on focal adhesion maturation and actin organization via the RhoA/ROCK pathway

Seo, Chang Ho; Furukawa, Katsuko; Montagne, Kévin; Jeong, Heonuk; Ushida, Takashi

doi:10.1016/j.biomaterials.2011.08.077

Cited by 171 publications

(141 citation statements)

References 39 publications

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“…3B, Micropillar-1, top). [80][81][82] On the other hand, if there is enough spacing between the pillars, actin filaments are constrained between the pillars, and the focal adhesions are present only on the side and/or the bottom of the pillars (Fig. 3B, Micropillar-1, bottom).…”

Section: Modulation Of the Actin Cytoskeleton Via Engineered Micro/namentioning

confidence: 99%

Topography Design Concept of a Tissue Engineering Scaffold for Controlling Cell Function and Fate Through Actin Cytoskeletal Modulation

Miyoshi

Adachi

2014

Tissue Engineering Part B: Reviews

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Section: Modulation Of the Actin Cytoskeleton Via Engineered Micro/namentioning

confidence: 99%

Topography Design Concept of a Tissue Engineering Scaffold for Controlling Cell Function and Fate Through Actin Cytoskeletal Modulation

Miyoshi

Adachi

2014

Tissue Engineering Part B: Reviews

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“…Adhesion is a key factor in determining the ability of a cell to effectively colonise a biomaterial, and thus to deposit a matrix that can serve as basis for newly formed tissue. Cells adhering to biomaterials with complex topographies have been shown to acquire a shape that adapts to the underlying substrate [5][6][7][8] , and convincing evidence has been presented to support the hypothesis that cell shape actually affects cell activity and differentiation fate [9][10][11] , although how cells can sense the geometrical features of endosseous implant surfaces and transduce them into pro-differentiation stimuli is still being actively investigated. Biomaterials that can control cell shape have thus the potential to provide cells with potent stimuli that can affect cell commitment toward a phenotype lineage, and investigating the 3D morphological conformation of a cell on a biomaterial surface is therefore of pivot importance to predict its behavior.…”

Section: Introductionmentioning

confidence: 99%

Osteoblasts preferentially adhere to peaks on micro-structured titanium

Lagonegro¹,

Trevisi²,

Nasi³

et al. 2018

Dent. Mater. J.

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The aim of the study was to investigate cell adhesion to micro-structured titanium. Osteoblastic MC3T3 cells were cultured on smooth (P) or sand-blasted/acid-etched (SLA) titanium discs and were observed at scanning electron microscope/focused ion beam (SEM/ FIB). Myosin II and actin microfilaments were labelled for epifluorescence microscopy. FIB revealed that cell adhesion initiated centrally and expanded to the cell periphery and that cells attached on the substrate by bridging over the titanium irregularities and adhering mostly on surface peaks. Gaps were visible between concave areas and cytoplasm and areas around ridges represented preferred attachment points for cells. A different myosin distribution was observed between samples and myosin inhibition affected cell responses. Taken together our data indicate that cells attach on micro-rough titanium by bridging over its irregularities. This is likely mediated by myosin II, whose distribution is altered in cells on SLA discs.

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“…Among these, Goffin et al employed micropatterning to modulate FA development in myofibroblasts and found that the FA length controls the transition of smooth muscle actin (SMA) into stress fibers in a tension-dependant manner [18]. Seo et al found that FA maturation and actin polymerization were promoted via the RhoA pathway when MSCs were cultured on microtopographical substrates [19]. However, so far, there are no reports on the synergistic study of FA modulation, matrix stiffness, and ECM ligands on stem cell differentiation; let alone the more important mechanistic studies of these interactions, which we would like to address in this article.…”

Section: Introductionmentioning

confidence: 99%

Insights into the Role of Focal Adhesion Modulation in Myogenic Differentiation of Human Mesenchymal Stem Cells

Lui

Xiong

et al. 2013

Stem Cells and Development

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We report the establishment of a novel platform to induce myogenic differentiation of human mesenchymal stem cells (hMSCs) via focal adhesion (FA) modulation, giving insights into the role of FA on stem cell differentiation. Micropatterning of collagen type I on a polyacrylamide gel with a stiffness of 10.2 kPa efficiently modulated elongated FA. This elongated FA profile preferentially recruited the b 3 integrin cluster and induced specific myogenic differentiation at both transcription and translation levels with expression of myosin heavy chain and a-sarcomeric actin. This was initiated with elongation of FA complexes that triggered the RhoA downstream signaling toward a myogenic lineage commitment. This study also illustrates how one could partially control myogenic differentiation outcomes of similar-shaped hMSCs by modulating FA morphology and distribution. This technology increases our toolkit choice for controlled differentiation in muscle engineering.

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The effect of substrate microtopography on focal adhesion maturation and actin organization via the RhoA/ROCK pathway

Cited by 171 publications

References 39 publications

Topography Design Concept of a Tissue Engineering Scaffold for Controlling Cell Function and Fate Through Actin Cytoskeletal Modulation

Topography Design Concept of a Tissue Engineering Scaffold for Controlling Cell Function and Fate Through Actin Cytoskeletal Modulation

Osteoblasts preferentially adhere to peaks on micro-structured titanium

Insights into the Role of Focal Adhesion Modulation in Myogenic Differentiation of Human Mesenchymal Stem Cells

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