Incorporation of bio-inspired microparticles within embryonnic stem cell aggregates for directed differentiation

Sullivan, Denise D.

27 May 2016

Embryonic stem cells (ESCs) are a unique cell population that can differentiate into all three embryonic germ layers (endoderm, mesoderm, and ectoderm), rendering them an invaluable cell source for studying the molecular mechanisms of embryogenesis. Signaling molecules that direct tissue patterning during embryonic development are secreted by ESC aggregates, known as embryoid bodies (EBs). As many of these signaling proteins interact with the extracellular matrix (ECM), manipulation of the ESC extracellular environment provides a means to direct differentiation. ECM components, such as glycosaminoglycans (GAGs), play crucial roles in cell signaling and regulation of morphogen gradients during early development through binding and concentration of secreted growth factors. Thus, engineered biomaterials fabricated from highly sulfated GAGs, such as heparin, provide matrices for manipulation and efficient capture of ESC morphogens via reversible electrostatic and affinity interactions. Ultimately, biomaterials designed to efficiently capture and retain morphogenic factors offer an attractive platform to enhance the differentiation of ESCs toward defined cell types. The overall objective of this work was to examine the ability of microparticles synthesized from both synthetic and naturally-derived materials to enhance the local presentation of morphogens to direct ESC differentiation. The overall hypothesis was that microparticles that mimic the ECM can modulate ESC differentiation through sequestration of endogenous morphogens present within the EB microenvironment.

Embryonic stem cells

Microparticles

Embryoid bodies

Heparin

Stem cell differentiation

The Role of CHD1 during Mesenchymal Stem Cell Differentiation

Baumgart, Simon

22 February 2016

No description available.

570

Mesenchymal stem cell differentiation

Transcriptional Regulation

Epigenetics

Biologie (PPN619462639)

Conditioning of Mesenchymal Stem Cells Initiates Cardiogenic Differentiation and Increases Function in Infarcted Hearts

Guyette, Jacques Paul

16 January 2012

Current treatment options are limited for patients with myocardial infarction or heart failure. Cellular cardiomyoplasty is a promising therapeutic strategy being investigated as a potential treatment, which aims to deliver exogenous cells to the infarcted heart, for the purpose of restoring healthy myocardial mass and mechanical cardiac function. While several cell types have been studied for this application, only bone marrow cells and human mesenchymal stem cells (hMSCs) have been shown to be safe and effective for improving cardiac function in clinical trials. In both human and animal studies, the delivery of hMSCs to infarcted myocardium decreased inflammatory response, promoted cardiomyocyte survival, and improved cardiac functional indices. While the benefits of using hMSCs as a cell therapy for cardiac repair are encouraging, the desired expectation of cardiomyoplasty is to increase cardiomyocyte content that will contribute to active cardiac mechanical function. Delivered cells may increase myocyte content by several different mechanisms such as differentiating to a cardiomyocyte lineage, secreting paracrine factors that increase native stem cell differentiation, or secreting factors that increase native myocyte proliferation. Considerable work suggests that hMSCs can differentiate towards a cardiomyocyte lineage based on measured milestones such as cardiac-specific marker expression, sarcomere formation, ion current propagation, and gap junction formation. However, current methods for cardiac differentiation of hMSCs have significant limitations. Current differentiation techniques are complicated and tedious, signaling pathways and mechanisms are largely unknown, and only a small percentage of hMSCs appear to exhibit cardiogenic traits. In this body of work, we developed a simple strategy to initiate cardiac differentiation of hMSCs in vitro. Incorporating environmental cues typically found in a myocardial infarct (e.g. decreased oxygen tension and increased concentrations of cell-signaling factors), our novel in vitro conditioning regimen combines reduced-O2 culture and hepatocyte growth factor (HGF) treatment. Reduced-O2 culturing of hMSCs has shown to enhance differentiation, tissue formation, and the release of cardioprotective signaling factors. HGF is a pleiotropic cytokine involved in several biological processes including developmental cardiomyogenesis, through its interaction with the tyrosine kinase receptor c-Met. We hypothesize that applying a combined conditioning treatment of reduced-O2 and HGF to hMSCs in vitro will enhance cardiac-specific gene and protein expression. Additionally, the transplantation of conditioned hMSCs into an in vivo infarct model will result in differentiation of delivered hMSCs and improved cardiac mechanical function. In testing our hypothesis, we show that reduced-O2 culturing can enhance hMSC growth kinetics and total c-Met expression. Combining reduced-O2 culturing with HGF treatment, hMSCs can be conditioned to express cardiac-specific genes and proteins in vitro. Using small-molecule inhibitors to target specific effector proteins in a proposed HGF/c-Met signaling pathway, treated reduced-O2/HGF hMSCs show a decrease in cardiac gene expression. When implanted into rat infarcts in vivo, reduced-O2/HGF conditioned hMSCs increase regional cardiac mechanics within the infarct region at 1 week and 1 month. Further analysis from the in vivo study showed a significant increase in the retention of reduced-O2/HGF conditioned hMSCs. Immunohistochemistry showed that some of the reduced-O2/HGF conditioned hMSCs express cardiac-specific proteins in vivo. These results suggest that a combined regimen of reduced-O2 and HGF conditioning increases cardiac-specific marker expression in hMSCs in vitro. In addition, the implantation of reduced-O2/HGF conditioned hMSCs into an infarct significantly improves cardiac function, with contributing factors of improved cell retention and possible increases in myocyte content. Overall, we developed a simple in vitro conditioning regimen to improve cardiac differentiation capabilities in hMSCs, in order to enhance the outcomes of using hMSCs as a cell therapy for the diseased heart.

mesenchymal stem cells

stem cell differentiation

cardiomyoplasty

cardiac mechanical function

Matrix Property-Controlled Stem Cell Differentiation for Cardiac and Skeletal Tissue Regeneration

Xu, Yanyi

January 2015

No description available.

Materials Science

Role of linker histone H1 in epigenetic regulation of pluripotency genes and Hox genes

Zhang, Yunzhe

27 May 2016

Linker histone H1 plays a key role in facilitating folding of higher order chromatin structure. Previous studies have shown that deletion of three somatic H1 subtypes together leads to embryonic lethality and that H1c/H1d/H1e triple knockout (TKO) embryonic stem cells (ESCs) display bulk chromatin decompaction. Following this initial work, we investigated the role of H1 and chromatin compaction in stem cell pluripotency and differentiation, as well as the regulation of Hox genes expression. We find that H1 TKO ESCs are more resistant to spontaneous differentiation, impaired in embryoid body differentiation, and largely blocked in neural differentiation. We present evidence that H1 contributes to efficient repression of the expression of pluripotency factors, Oct4 and Nanog, and participates in establishment and maintenance of DNA methylation and histone modification necessary for silencing pluripotency genes during stem cell differentiation and embryogenesis. In addition, we find reduced expression of a distinct set of Hox genes in embryos and ESCs, respectively. Furthermore, by characterizing H1c−/−; H1d−/−; and H1e−/− single-H1 null ESCs established in this study, we showed that individual H1 subtypes regulated specific Hox genes in ESCs. Finally, we demonstrate that the levels of H3K4me3 were significantly diminished at the affected Hox genes in H1 TKO- and single-H1 KO- ESCs, whereas H3K27me3 occupancy is modestly increased at specific Hox genes. Our results suggest that marked reduction of H1 levels and decondensation of bulk chromatin affect the expression of pluripotency genes and Hox genes in embryos and ESCs, which may be in part mediated through establishment and maintenance of epigenetic marks.

Histone h1

Hox genes

Stem cell differentiation

Pluripotency gene

Oct4

Nanog

Epigenetic marks

Characterization of the Epigenetic Signature Underlying Early Myogenic Differentiation

Hamed, Munerah

30 August 2019

Although skeletal myogenesis is largely controlled by myogenic regulatory factors, epigenetic modifications have recently emerged as an essential regulatory mechanism of gene expression. Molecular regulation of stem cell differentiation is exerted through both genetic and epigenetic factors over distal enhancer regions. Understanding the mechanistic action of active or poised enhancers is therefore, imperative for the control of stem cell differentiation. Based on the genome-wide co-occurrence of different epigenetic marks in proliferating myoblasts, we have generated a chromatin state model to profile differentiation- and rexinoid-responsive histone acetylation in early myoblast differentiation. Here, we delineate the functional mode of transcription regulators during early myogenic differentiation using genome-wide chromatin state association. We define a role of transcriptional coactivator p300, when recruited by muscle master regulator MyoD, in the establishment and regulation of myogenic loci at the onset of myoblast differentiation. In addition, we reveal an enrichment of loci-specific histone acetylation at p300 associated active or poised enhancers, mainly when enlisted by MyoD. We have previously established that bexarotene, a clinically approved agonist of retinoid X receptor (RXR), promotes the specification and differentiation of skeletal muscle lineage. Hence, we investigated the genome-wide impact of rexinoids on myogenic differentiation and uncovered a new mechanism of rexinoid action, which is mediated by the nuclear receptor and largely reconciled through direct regulation of MyoD gene expression. In addition, we determined rexinoid-responsive residue-specific histone acetylation at a distinct chromatin state associated with MyoD and myogenin. Finally, through ChIP-seq and RNA-seq analyses, we have identified dystroglycan (Dag1) as a differentiation-dependent and a rexinoid-responsive model target, and we revealed a possible co-regulation of Dag1 by p300 and MyoD accompanied by enrichment of loci-specific histone acetylation. Taken together, we provide novel molecular insights into the regulation of myogenic enhancers by p300 in concert with MyoD. Furthermore, we provide novel mechanistic perceptions into the interplay between RXR signaling and chromatin states pertinent to myogenic programs in early myoblast differentiation. Our studies present a valuable insight for driving condition-specific chromatin state or enhancers pharmacologically to treat muscle-related diseases and for the identification of additional myogenic targets and molecular interactions for therapeutic development.

Histone acetyltransferase

p300

Nuclear receptor

RXR

Gene regulation

Chromatin

Stem cell differentiation

Epigenetics

Forward programming of human pluripotent stem cells to a megakaryocyte-erythrocyte bi-potent progenitor population : an in vitro system for the production of platelets and red blood cells for transfusion medicine

Dalby, Amanda Louise

January 2018

There exists a need to produce platelets in vitro for use in transfusion medicine, due to increased platelet demands and short shelf life. Our lab uses human induced pluripotent stem cells (iPSCs), as an attractive alternative supply, as iPSCs can be cultured indefinitely and differentiate into almost any cell type. Using a technique called forward programming, we over express three key haematological transcription factors (TFs), pushing iPSCs towards the megakaryocyte lineage, to produce mature megakaryocytes, the platelet precursor cell type. A major limitation of the forward programming technique is a reliance of lentiviral transduction to overexpress the three TFs, which leads to a number of issues including heterogeneity and high experimental costs. To overcome this, I have developed an inducible iPSC line by inserting the forward programming TFs into a genomic safe harbour, using genome editing techniques. TF expression is strictly controlled, with the TFs expressed only after chemical induction. Inducing forward programming is an efficient method for producing mature megakaryocytes and these cells maintain higher purity in long-term cultures, when compared to cells produced by the lentiviral method. Removing the requirement of lentiviral transduction is a major advancement, making forward programming more amenable to scaling-up, thus moving this technology closer towards our goal of producing in vitro platelets for use in transfusion medicine. I have also shown that forward programming generates a bi-potent progenitor population, from which erythroblasts can be generated, by altering only media conditions. As for megakaryocyte cultures, inducing forward programming improves the purity of erythroblasts produced, compared to the lentiviral method. I have developed single cell progenitor assays combined with index sorting of different cell surface markers, to allow retrospective analysis of cells which successfully generate colonies. The aim of this work is to better characterise the progenitor cells produced by forward programming, to allow further study of this cell type. Single cell RNA-seq of megakaryocytes revealed heterogeneity in long-term cultures and also identified novel candidate surface markers that may help to further characterise the progenitor cell population.

Designing ionic-complementary hydrogels for bone tissue repair

Castillo Diaz, Luis Alberto

January 2015

In recent years, the degradation and subsequent loss of tissues is an issue that has affected people worldwide. Although there are treatments addressing the degradation of tissues, such treatments involve complicated and expensive procedures, where full tissue regeneration is not achieved. For these reasons, in recent years, tissue engineering has developed cutting-edge biomaterials capable of inducing effective tissue regeneration both under cellular or acellular conditions. Peptide hydrogels are versatile biomaterials composed of the basic components of life amino acids, which act as building blocks to form hierarchical structures, which subsequently go on to form well-defined scaffolds. Biomaterials have been widely used for the culture of mammalian cells, tissue engineering, regenerative medicine, drug delivery, etc. This is thanks to their capability of providing a three-dimensional architecture to cells, which mimics the natural architecture of the extracellular matrix (ECM). Peptide- based hydrogels can be easily functionalised with active biological cues, which can direct the cellular response. It has been shown that the ionic-complementary FEFEFKFK hydrogel, succeeded to support the culture of mammalian cells such as bovine chondrocytes. In this work, we used the same FEFEFKFK hydrogel to investigate the capability of this hydrogel to support the three-dimensional culture of both human osteoblasts (hOBs), and human mesenchymal stem cells (hMSCs) for bone regeneration applications. To achieve this goal, hOBs were cultured within both FEFEFKFK (non-functionalised) and RGD-FEFEFKFK (functionalised) gels. Then the suitability of the FEFEFKFK gels to induce cellular proliferation, synthesis of bone ECM and mineralisation was explored. In addition, taking advantage of the inherent plasticity of hMSCs, we also investigated the capability of the FEFEFKFK gel to foster the osteogenic differentiation of hMSCs, and subsequently to induce bone mineralisation in 3-D under osteogenic stimulation. Based on the results obtained in this work, the FEFEFKFK gel arises as a promising biomaterial for both bone and dental tissue regeneration applications.

617.4

Development of DNA-binding Synthetic Molecules Toward Selective Gene Regulation and Cell Fate Control / DNA結合性合成化合物による選択的な遺伝子発現制御と細胞の運命制御の検討

Taniguchi, Junichi

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第20940号 / 理博第4392号 / 新制||理||1631(附属図書館) / 京都大学大学院理学研究科化学専攻 / (主査)教授 杉山 弘, 教授 三木 邦夫, 教授 秋山 芳展 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

DNA-binding molecules

Pyrrole-imidazole polyamides

Gene expression

Epigenetics

Stem cell differentiation

400

Engineered Biomaterials for Human Neural Stem Cell Applications

Ma, Weili

January 2019

Within the last decade, neurodegenerative diseases such as Alzheimer’s and Parkinson’s have emerged as one of the top 5 leading causes of death globally, and there is currently no cure. All neurodegenerative diseases lead to loss of the functional cells in the nervous system, the neurons. One therapeutic approach is to replace the damaged and lost neurons with new, healthy neurons. Unfortunately, this is a difficult endeavor since mature neurons are not capable of cell division. Instead, researchers are turning to neural stem cells, which are able to self-renew and be rapidly expanded before being differentiated into functional cell phenotypes, such as neurons, allowing for large numbers of cells to be generated in vitro. Controlled differentiation of human neural stem cells into new neurons has been of interest due to the immense potential for improving clinical outcomes. Adult neural stem cell behavior, however, is not well understood and the transplanted stem cells are at risk for tumorigenesis. The focus of this dissertation is the development of engineered biomaterials as tools to study human neural stem cell behavior and neurogenesis (differentiation). A novel cell penetrating peptide was developed to enhance intracellular delivery of retinoic acid, a bioactive lipid known to induce differentiation. A hydrogel platform fabricated from hyaluronic acid, a naturally-occurring polysaccharide found in brain extracellular space, was designed to serve as a biomimetic soft substrate with similar mechanical properties to the brain. The biological behavior of the stem cells was characterized in response to chemical and physical cues. / Bioengineering

Bioengineering

Materials Science

Hyaluronic Acid

Hydrogel

Neural Stem Cells

Peptide

Retinoic Acid

Stem Cell Differentiation