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Synthetic Substrata to Instruct Human Pluripotent Stem Cell Fate

2012
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Release : 2012
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Book Synopsis Synthetic Substrata to Instruct Human Pluripotent Stem Cell Fate by :

Download or read book Synthetic Substrata to Instruct Human Pluripotent Stem Cell Fate written by . This book was released on 2012. Available in PDF, EPUB and Kindle. Book excerpt: Human pluripotent stem (hPS) cells have the remarkable capacity to self-renew indefinitely and differentiate into desired cell types. They can serve as a virtually unlimited supply of cells for applications ranging from drug screening to cell therapies to understanding human development. Reaping the promise of hPS cells hinges on effective defined culture and differentiation conditions. Efforts to generate chemically-defined environments for hPS cell propagation and directed differentiation have been hindered by access to only a handful of ligands to target hPS cells. Additionally, progress has been limited also by lack of knowledge regarding the relevant functional properties of the cell culture substratum. To address these problems, I first employed forward-chemical-genetics coupled with self-assembled monolayer technology to identify novel peptides that bind to hPS cell-surface receptors. I then developed a controlled synthesis of hydrogels with tailored peptide display and mechanical properties. This approach yielded synthetic hydrogels with specific mechanical properties that function in a defined medium to robustly support hPS cell self-renewal. Finally, by starting from molecular level understanding that matrix elasticity regulates developmental pathways, I generated a highly efficient hydrogel platform that restricts hPS cell differentiation to neurons, even without soluble inductive factors. These results indicate that insoluble cues can be important information conduits to guide hPS cell fate decisions. I envision that the blueprint provided by this work can be utilized to devise new materials to guide hPS cell fate.

Synthetic Surfaces to Probe Human Pluripotent Stem Cell Fate Decisions

2015
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Release : 2015
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Book Synopsis Synthetic Surfaces to Probe Human Pluripotent Stem Cell Fate Decisions by :

Download or read book Synthetic Surfaces to Probe Human Pluripotent Stem Cell Fate Decisions written by . This book was released on 2015. Available in PDF, EPUB and Kindle. Book excerpt: The field of regenerative medicine promises to restore function to failing organs and tissues in patients with debilitating degenerative diseases or injuries. One branch of the field focuses on discovering methods to induce endogenous tissues to regenerate or repair themselves. The other branch seeks to produce replacement tissues and organs in vitro to serve as a limitless source for transplants. Human pluripotent stem cells--with the ability to self-renew indefinitely in culture and differentiated into virtually any functional cell type--hold promise as source material for regenerative medicine. In order to achieve this promise, however, we must develop methods to control the proliferation and differentiation of the cells and the methods must keep them free of contaminative immunogens or pathogens. This thesis focuses on the juncture of these two goals. Initially, we developed of the first synthetic surface capable of supporting human pluripotent stem cells. This synthetic surface interacts with cell surface glycosaminoglycans, and I aimed to determine how insoluble cues influence the signaling mechanisms involved in cell fate determination. First, I developed peptide-presenting surfaces tailored to the changing adhesion needs of pluripotent stem cells as they differentiated into neural progenitor cells and motor neurons (Chapter 2). I demonstrated that cells differentiate more robustly toward endoderm and mesoderm lineages when cultured on GAG-binding surfaces. Further, I probed the molecular mechanisms involved and showed that integrin activation of Akt via integrin-linked kinase inhibits mesendoderm differentiation (Chapter 3). We also analyzed the effects of mechanical cues on stem cell fate. Human pluripotent stem cells require a surface of sufficient stiffness to maintain pluripotency. When cultured on softer surfaces, they rapidly differentiate into neurons, and we demonstrated that this process is governed by the mechanosensitive transcriptional coactivator Yes-associated protein (Chapter 4). Cumulatively, this thesis dissects and reveals mechanisms by which insoluble cues control human fate decisions. The continued research into the crosstalk between insoluble and soluble signaling mechanisms will facilitate the goals of regenerative medicine.

Tailored Surfaces for Investigating Human Pluripotent Stem Cells

2012
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Release : 2012
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Book Synopsis Tailored Surfaces for Investigating Human Pluripotent Stem Cells by :

Download or read book Tailored Surfaces for Investigating Human Pluripotent Stem Cells written by . This book was released on 2012. Available in PDF, EPUB and Kindle. Book excerpt: Human embryonic and induced pluripotent stem cells, collectively known as hPS cells, hold great promise for the fields of regenerative medicine, developmental biology, and drug discovery. Elucidating the molecular mechanisms underlying their proliferation and differentiation is vital for realizing their potential. My research has focused on defining the molecular interactions that mediate hPS cell adhesion and self- renewal. To accomplish this goal, we assayed surfaces that mimic soluble signaling factors, mediate cell-cell interactions, or display peptides derived from extracellular matrix (ECM) proteins. I focused initially on the adhesion receptor E-cadherin, but my latter work used surfaces displaying synthetic peptides to engage other cell surface molecules. A key feature of these tailored surfaces is our ability to attribute cellular responses to the specific interactions between the cell and underlying substratum. The major accomplishment of this research was the development of a synthetic substrate for hPS cell propagation. The effective substrates displayed heparin-binding peptides that can interact with cell surface glycosaminoglycans (GAGs). My results also reveal that adhesion is not the sole prerequisite for self-renewal; integrin-binding surfaces did not maintain hPS cells in their pluripotent state. The chemically defined substratum highlights the utility of engaging cell surface GAGs and provides the foundation for investigating the influence of cellular adhesion on cell fate. To complement this work, I expanded our tailored surface strategy to target differentiated cells. In principle, surfaces modified with synthetic peptides can support adhesion by mimicking the ECM, but synthetic peptides typically lack affinity or selectivity for specific adhesion receptors. In contrast, organic chemistry can afford compounds that are highly selective. We hypothesized that selective small molecule integrin antagonists, when immobilized, would support adhesion and activate signaling. Indeed, surfaces decorated with a selective alphavbeta3 integrin-targeting molecule promoted both cellular adhesion and integrin activation. I anticipate that peptidomimetics will add to our arsenal of building blocks for generating tailored surfaces. Surfaces displaying highly selective ligands can illuminate the contributions of specific adhesion receptors to signaling cascades and perhaps even control stem cell differentiation. In conclusion, my research has afforded new, practical methods for propagating and manipulating pluripotent cells and their derivatives.

Expansion of Human Induced Pluripotent Stem Cells on Synthetic Substrate in Defined Medium

2012 Stem cells
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Release : 2012
Genre : Stem cells
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Book Rating : 349/5 ( reviews)

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Book Synopsis Expansion of Human Induced Pluripotent Stem Cells on Synthetic Substrate in Defined Medium by : Huantong Yao

Download or read book Expansion of Human Induced Pluripotent Stem Cells on Synthetic Substrate in Defined Medium written by Huantong Yao. This book was released on 2012. Available in PDF, EPUB and Kindle. Book excerpt: Human induced pluripotent stem cells (hiPSCs) have the potential to generate patient-specific cells to treat many incurable diseases by cell replacement therapy. However, so far the culture of hiPSCs depends greatly on feeder cells or Matrigel which has safety issues. Thus, chemically defined substrates that could provide niches necessary for cell attachment and proliferation are preferred for clinical application of hiPSCs. Recently, Corning Life Sciences has developed synthetic peptide-functionalized cell culture surface, referred to as Corning RTM Synthemax(TM) that support self-renewal and differentiation of human embryonic stem cell (hESC). In this work, we have collaborated with Corning to investigate the attachment, proliferation, and differentiation of hiPSCs on the Synthemax substrate. We demonstrated that iPS cells retained stable proliferation and pluripotency marker protein expression after growing on the Synthemax substrate for ten consecutive passages. Further examination reveals that integrins alphaVbeta5 mediates attachment to the substrate. Moreover, we observed hiPSCs colonies were more compact on the Synthemax surface. This may be due to less activation of beta-catenin-mediated Wnt signaling pathway in cells on the synthetic peptide surface. In hiPSCs grown on the Synthemax Surface, we also found denser actin filaments in the cell-cell interface and down-regulation of vinculin and up-regulation of zyxin, indicating the reorganization of cytoskeleton structure inside cells in response to cell-matrix interaction.

Designing Synthetic Culture Systems for Human Stem Cell Culture

2012
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Release : 2012
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Book Synopsis Designing Synthetic Culture Systems for Human Stem Cell Culture by : Naomi Kohen

Download or read book Designing Synthetic Culture Systems for Human Stem Cell Culture written by Naomi Kohen. This book was released on 2012. Available in PDF, EPUB and Kindle. Book excerpt: Human embryonic stem (hES) cells and human induced pluripotent stem (hips) cells can differentiate into all cell types of the body and therefore hold great therapeutic value. Applications ranging from in situ regenerative medicine, ex vivo tissue generation, and drug screening have consequently been proposed for these pluripotent cells. However, the current culturing techniques for both hES and hiPS cells hinder the clinical feasibility of their use. Pluripotent cell culture protocols have historically involved the use of animal products, which can introduce pathogens as well as limit the scalability and reproducibility of these platforms. While media formulations have been optimized to include only human or recombinant proteins, the current gold standard for human stem cell culture substrate is still Matrigel, an excretion from a mouse tumor that resembles the extra cellular matrix. It is therefore crucial to engineer materials that replace Matrigel in human pluripotent stem cell culture. Despite the complexity of the native cell niche, key characteristics of the cell niche must be considered and chosen for emulation in constructing a synthetic system to replace Matrigel. Mechanical environment and paracrine signaling were deemed to be parameters that were both crucial for such an application and feasible to incorporate. Toward that end, a process to create tunable cell culture surfaces to replace Matrigel, and to conduct fundamental studies on the effects of mechanical environment and paracrine signaling was developed in this dissertation. A number of strategies for patterning hydrogels were considered for the creation of this synthetic human pluripotent substrate, as the hydrogel could provide mechanical cues to the cells and the patterning would control paracrine signaling by regulating cell colony size and spacing. Ultimately, a strategy involving concurrent UV illumination and microcontact printing of a UV activated crosslinker onto a low swelling hydrogel was selected, as it showed the highest pattern fidelity of the strategies explored, due to its minimization of ink diffusion. Hydrogels as compliant as 140 Pa could be patterned with this technique, and such hydrogels were shown to support hES cells in the short term. To emphasize the limitations of Matrigel based cell culture platforms, the physical properties of Matrigel on variety of typical cell culture surfaces were studied, and it was found that the substrate beneath Matrigel was capable of influencing cell behavior such as proliferation and pluripotency, by altering the physical properties of Matrigel. The need to create surfaces with defined cell colony sizes and spacing, thereby introducing standardization into the cell culture platform, was further emphasized by the results of our short term study conducted on the effects of mechanical environment on hES cells. While proliferation was influenced by substrate modulus, pluripotent gene expression was too variable to show any significant differences as a function of substrate modulus. The patterning methodology developed in this dissertation for creating a modular synthetic culture surface for human pluripotent stem cells can be used not only for the maintenance of the pluripotency of the cells, but also for the directed differentiation of the cells. As a step toward using these platforms for directed differentiation protocols, the patterned surfaces were shown to support cardiomyocytes directly differentiated from iPS cells from a patient with long QT3 syndrome, with cells beating synchronously within a cell colony.

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