Three-dimensional extracellular matrix-directed cardioprogenitor differentiation: Systematic modulation of a synthetic cell-responsive PEG-hydrogel

Jeffrey Alan Hubbell, Matthias Lütolf
2008
Article

Résumé

We show that synthetic three-dimensional (3D) matrix metalloproteinase (MMP)-sensitive poly(ethylene glycol) (PEG)-based hydrogels can direct differentiation of pluripotent cardioprogenitors, using P19 embryonal carcinoma (EC) cells as a model, along a cardiac lineage in vitro. In order to systematically probe 3D matrix effects on P19 EC differentiation, matrix elasticity, MMP-sensitivity and the concentration of a matrix-bound RGDSP peptide were modulated. Soft matrices (E=322+/-64.2Pa, stoichiometric ratio: 0.8), mimicking the elasticity of embryonic cardiac tissue, increased the fraction of cells expressing the early cardiac transcription factor Nkx2.5 around 2-fold compared to embryoid bodies (EB) in suspension. In contrast, stiffer matrices (E=4036+/-419.6Pa, stoichiometric ratio: 1.2) decreased the number of Nkx2.5-positive cells significantly. Further indicators of cardiac maturation were promoted by ligation of integrins relevant in early cardiac development (alpha(5)beta(1,) alpha(v)beta(3)) by the RGDSP ligand in combination with the MMP-sensitivity of the matrix, with a 6-fold increased amount of myosin heavy chain (MHC)-positive cells as compared to EB in suspension. This precisely controlled 3D culture system thus may serve as a potential alternative to natural matrices for engineering cardiac tissue structures for cell culture and potentially therapeutic applications.

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https://infoscience.epfl.ch/record/124864?ln=fr

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Jeffrey Alan Hubbell, Matthias Lütolf
2008
Article

Résumé

Official source

https://infoscience.epfl.ch/record/124864?ln=fr

À propos de ce résultat

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Publications associées (35)

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Publications associées (35)

Muscle degenerative disorders, such as Duchenne muscular dystrophy, have a profound impact on the quality of life and survival of patients. Transplantation of myoblasts to restore muscle function has been discouraging since these cells die and don't migrate but it has more recently been reported that muscle stem cells, known as satellite cells, have an extraordinary potential to contribute to muscle fiber regeneration, home to their niche and replenish the stem cell pool when injected freshly into damaged muscle. These cells however quickly lose their regenerative potential when cultured in vitro. Adult stem cells are known to be regulated by their microenvironment through a complex mixture of signals including soluble factors, matrix bound proteins, neural input and mechanical properties and the identification of extrinsic factors that can regulate muscle stem cell quiescence and self-renewal has been a focus of research in the Blau lab. Strikingly, recent studies in the Blau lab have shown that muscle stem cells cultured on compliant hydrogels coated with laminin were more viable than those cultured on tissue culture plastic and robustly contributed to muscle regeneration when transplanted into irradiated mouse leg muscles. The aim of this project was to follow up on these findings and to further elucidate the role biophysical and biochemical microenvironmental cues play in the regulation of muscle stem cell fate. Hydrogels have emerged as a popular material to recreate the stem cell niche in vitro due to their biocompatibility, high water content, tissue-like elasticity and diffusive properties and were employed here to fabricate substrates of varying rigidities. The physicochemical properties and tethered protein densities of a range of poyl(ethylene glycol) hydrogels were first characterized to define a suitable set of cell culture substrates. Gel stiffness could be linearly modulated from 2.5 to 45 kPa and the ligand density was found to be in the low femtomolar range. ELISA showed similar protein density on gels of different stiffnesses but immunofluorescence could not fully confirm this. Committed myoblasts were then seeded on these gels and shown to respond to substrate stiffness and ligand density in terms of morphology. Lastly, freshly isolated muscle stem cells were cultured on these gels and on rigid tissue culture plastic and shown to spread more, be more viable and grow more rapidly on stiffer gels as compared to soft ones. Myogenic progression was retrospectively analysed using immunohistochemistry but no differences between culture conditions were observed. Based on the influences of gel rigidity and ligand density observed in vitro, an in vivo assay, the ultimate test of stem cell function, is currently underway.

2009

Chargement

MMP-sensitive Hydrogels for Induction of Embryonic Stem Cell Differentiation

Céline Gandar

During embryonic development, the extracellular matrix plays a critical role in regulating the differentiation of embryonic stem cells into specific cell lineages. MMP-sensitive PEG hydrogel is a material that has the ability to be degraded by the cells themselves upon secretion of proteases called MMPs. This synthetic material presents a great potential for mimicking the extracellular matrix due to the numerous bio-active peptides that can be incorporated. The suitability of this gel with mouse embryonic stem cells (ESCs) was studied for the first time in this project and its ability of supporting angiogenesis from embryoid bodies (EBs) was investigated. I encapsulated EBs in MMP-sensitive gel containing RGD and/or Wnt5a peptide and showed that sprouting activity could occurred after 14 days culture in a specific media. Even though the nature of the sprouting cells could not be totally determined, a percentage of them was shown to express the endothelial marker CD31. I also demonstrated the positive effect of RGD on the viability of EBs by analyzing their morphology as well as monitoring the cell proliferation over time. In addition to RGD, Wnt5a-derived peptide was incorporated in the gel to investigate its ability to not only support but also to enhance angiogenic activity. Indeed, in previous studies, this protein was reported as a factor increasing motility and invasion of ESCs-derived endothelial cells. However, due to high variations in EBs responses, the effect of Wnt5a could not be emphasized. Even though those results need to be repeated and further experiments are required to answer many new questions, they point to promising prospects for tissue engineering in terms of designing synthetic material that can encapsulate stem cells and promote desired differentiation thanks to specific incorporated ligands

2009

Chargement

The effect of matrix characteristics on fibroblast proliferation in 3D gels

Martin Ehrbar, Jeffrey Alan Hubbell, Matthias Lütolf, Simone Rizzi

Engineering synthetic hydrogels on a molecular basis to introduce natural features that are important in instructing cell behavior is becoming increasingly crucial in biomaterial-based approaches for regenerative medicine and in cell biology to study cell–matrix interactions in three-dimensions (3D). Here, we used collagen gels and exploited the design flexibility of the biological, biochemical and physical characteristics offered by a PEG-based hydrogel system to systematically study the effect of specific extracellular microenvironments on the behavior of primary human fibroblasts in 3D. We firstly found that the proliferation profiles of fibroblasts from different patients cultured within collagen gels (3D) differed significantly from their behavior observed on tissue culture plastic (2D). Furthermore, using the biomimetic PEG-based matrix we showed that cell proliferation in 3D could be selectively manipulated via alteration of the gel characteristics. In particular, this study revealed that, in spite of matrix sensitivity to proteases (e.g. MMP) and the presence of cell-integrin binding sites, at high stiffness (elastic modulus, G′ >1200 Pa) the matrix acts as a barrier for cells cultured in 3D. Finally, a comparison between the biomimetic PEG-based and collagen gels indicated that differences in their viscoelastic behaviours, determined by the nature of network structures and cross-links, may influence the mechanism(s) cells employ to remodel their 3D extracellular microenvironment. In conclusion, these studies highlight that for proliferation in 3D, compared to 2D, cells require strategies to overcome the physical impediment posed by the matrix. We also demonstrate that by exploiting the design flexibility of the characteristics offered by these biomimetic hydrogels, it is possible to separately investigate complex aspects characterizing the cell–matrix interactions in 3D; this has the potential to have great impact in regenerative medicine, as well as in cell biology and cancer research.

Elsevier2010

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2009

The effect of matrix characteristics on fibroblast proliferation in 3D gels

Martin Ehrbar, Jeffrey Alan Hubbell, Matthias Lütolf, Simone Rizzi

Elsevier2010