DIRECTION OF INDUCED PLURIPOTENT STEM CELL DIFFERENTIATION BY ENDOTHELIAL CELL SECRETOME

DiVincenzo, Lola S.

07 August 2015

No description available.

Biomedical Research

Biology

stem cells

induced pluripotent stem cells

regenerative therapy

cardiac regeneration

myocardial infarction

exosome

Investigating the Roles of Neurogenin 3 in Human Pancreas and Intestine Development and Disease

McGrath, Patrick Sean

03 June 2016

No description available.

Developmental Biology

pluripotent stem cells

endocrine cells

pancreas

intestine

diabetes

endoderm

Azacitidine is a potential therapeutic drug for pyridoxine-refractory female X-linked sideroblastic anemia / アザシチジンはピリドキシン不応性の女性X連鎖性鉄芽球性貧血の治療薬となり得る

Omune(Morimoto), Yuki

23 March 2022

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23777号 / 医博第4823号 / 新制||医||1057(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 江藤 浩之, 教授 寺田 智祐, 教授 小川 誠司 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

induced pluripotent stem cells

anemia

Azacitidine

X-linked sideroblastic anemia

490

Simple derivation of skeletal muscle from human pluripotent stem cells using temperature-sensitive Sendai virus vector / 温度感受性センダイウイルスベクターを用いてヒト多能性幹細胞から骨格筋細胞を簡便に作製する方法

TAN, GHEE WAN

23 March 2022

京都大学 / 新制・課程博士 / 博士(医学) / 甲第23812号 / 医博第4858号 / 新制||医||1059(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 金子 新, 教授 山下 潤, 教授 朝長 啓造 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

human pluripotent stem cells

skeletal muscle

Sendai virus

Myod1

differentiation method

disease modeling

490

Mechanism of Blood Maturation Induced by Hedgehog Inhibition in Pluripotent Sources

Mechael, Rami

10 1900

<p>The generation of hematopoietic progenitors from human pluripotent cell sources for use in personalized medicine is an attainable goal for the ease of clinical intervention using these cells. Furthermore, generated platelets and mature red blood cells are enucleated which allows for the use of induced pluripotent stem cells as a starting source or other sources of genetic manipulation. Generating these cells has proven difficult as the cells appear to be stuck in a primitive state of differentiation and do not mature into an adult phenotype. This thesis shows that inhibition of the hedgehog signaling pathway early in the differentiation of pluripotent stem cells induces a maturation towards definitive hematopoiesis. Generated erythroid cells were shown to express beta globin at the transcript as well as protein level. This maturation effect was confirmed to occur through central hedgehog repressor, Gli3R, through genetic manipulation. Further interrogation of this mechanism showed that globin regulation was not mediated by chromatin methylation by the polycomb repressive complex. Finally, Gli3R was also shown to not act as a transcription factor influencing globin expression directly and is therefore engaging separate regulatory mechanisms. This data provides great strides towards the generation of clinically relevant hematopoietic populations from pluripotent sources, however Gli3R’s direct mechanism of action remains to be determined.</p> / Master of Science (MSc)

human pluripotent stem cells

hematopoiesis

hedgehog signalling

epigenetics

Cell Biology

Cell Biology

FUNCTIONAL CHARACTERIZATION OF PUTATIVE MITOTIC BOOKMARKING FACTORS IN PLURIPOTENCY MAINTENANCE

Deng, Xiaoxiao (Daisy)

January 2018

Pluripotent stem cells are a special population of stem cell with indefinitely self-renewal and unlimited differentiation capability, which makes them an attractive avenue for regenerative medicine and disease modeling. Therefore, it is important to understanding the fundamental mechanisms that govern and maintain their pluripotent state. A phenomenon termed mitotic bookmarking has recently been suggested as a potential mechanism involved in the stable propagation of cellular identity through the cell cycles. Candidate-based studies have identified mitotic bookmarking factors that are retained on the mitotic chromatin and preserve the transcriptional memory of the cell. Nevertheless, there is a poor understanding of which proteins can serve as mitotic bookmarks, as well as the chromatin dynamics of bookmarked sites during mitosis and the start of the G1 phase. We have previously identified a list of putative mitotic bookmarking factors in pluripotent stem cells, from which we tested the role of PARP1, HDGF, and PSIP1 as potential bookmarks for the propagation of the pluripotent state through mitosis. Here we showed that the absence of PARP1 at the M-G1 transition impairs self-renewal capability of pluripotent stem cells without affecting the proliferation and cell cycle progression. Conclusive evidence that establishes a role for HDGF or PSIP1 in mitotic bookmarking of pluripotent stem cells has yet to emerge. However, our work provides a new avenue for exploring the functional importance of mitotic bookmarks in pluripotent maintenance. / Thesis / Master of Science (MSc)

Mitotic Bookmarking

Hdgf

Parp1

Psip1

Pluripotent Stem Cells

Cell Fate Regulation

The derivation and utility of in vitro organoids from human pluripotent stem cells

Nadkarni, Rohan R.

22 November 2018

Human pluripotent stem cells (hPSCs) have the ability to self-renew and differentiate into all specialized body cells, providing material suitable for studying basic biology, modeling disease, and for regenerative medicine. The differentiation of hPSCs into functional cell types has been further enhanced by the production of organoids, miniature 3D organ-like structures that mimic the architecture and function of their in vivo counterparts, representing more physiologically relevant models of native tissues than monolayer cultures. Our initial aim was to differentiate hPSCs into lung epithelial organoids in vitro, and we hypothesized that applying knowledge of signaling cues during embryonic development to the dish would produce lineage-specific tissue. Using a multi-stage differentiation strategy, we derived organoids sharing properties with the developing lung as well as intestine. From this work, we learned the importance of purification, selection, and using singularized precursor cells to produce populations of bona fide lineage-restricted organoids. Upon developing a type of intestinal organoid technology from hPSCs not reported before, we shifted our focus to the intestine. We generated cystic intestinal epithelial organoids called enterospheres (hEnS) in vitro from hPSCs, which mimic structural and cell type properties of the native small intestinal epithelium. hEnS growth, differentiation, and long-term culture can be controlled by modulating media conditions. Importantly, hEnS are functional in that they elicit an innate immune response upon treatment with enteric pathogens. We established hEnS as an attractive in vitro model system for studying human gastrointestinal biology. We then developed an automated hEnS imaging assay to measure responses to growth factors, bacterial products, and enteric bacteria themselves. In doing so, we demonstrated the utility of hEnS as a germ-free system for studying host-microbe interactions and intestinal maturation. Finally, we investigated the expression of protein markers of intestinal maturation in tissue sections of primary human intestine spanning gestation, and made observations that are different from those reported in mice. Overall, our work provides new and important insights into hPSC differentiation, organoid technologies, and intestinal development in humans. / Thesis / Doctor of Philosophy (PhD)

Human pluripotent stem cells

In vitro differentiation

Organoids

Intestinal organoids

Enterospheres

Lung organoids

Intestinal maturation

Human Stem Cell Models Identify Targets of Healthy and Malignant Hematopoietic Regulation

Reid, Jennifer

January 2020

Hematopoiesis is the highly regenerative process of producing billions of blood cells each day, including white blood cells, red blood cells, and platelets. Given the relatively short life span of these mature cells, hematopoiesis is dependent on stem and progenitor cells to generate renewed progeny, which represents a tightly regulated process. This includes cell intrinsic and external factors, and where dysregulation can lead to anemia and cancer. As such, the hematopoietic hierarchy has been intensely studied for nearly a century and represents a gold standard model of cell fate and developmental biology, in research and clinical applications. Cellular models, such as in vitro culture and human-mouse xenografts in vivo, have been developed to explain complex phenomena pertaining to hematopoiesis and also interrogate processes which are too invasive to study in humans. Hematopoietic generation is required beyond sustaining homeostasis, and progenitors can be damaged through cytotoxic injuries such as radiation and standard chemotherapy, and also undergo leukemic transformation. There are two main treatment modalities for leukemia patients (a) receiving a stem cell transplant, and (b) drug or radiation-based therapy. In the former, shortages of donors and stem cells has remained an unmet clinical need for decades. In the latter, selective targeting of genetic mutations has become a successful standard-of-care in leukemias such as chronic myelogenous leukemia and acute promyelocytic leukemia. However, in the most common adult hematologic malignancy, chronic lymphocytic leukemia (CLL), similar targeting therapies have not been developed. Altogether, shortages of stem cells from healthy donors, chemotherapy-induced immune dysfunction, and a lack of targeted therapies, all reinforce the immediate need for innovative cellular models to address these clinical problems. To generate additional sources of human hematopoietic progenitors for laboratory study, human PSCs have been used. Unlike hematopoietic progenitor cells collected from healthy and leukemic donors, human pluripotent stem cells (PSC) can be easily propagated and expanded in vitro. PSCs can generate hematopoietic progenitor cells, but they remain poorly understood and have not been robustly applied to solve the aforementioned deficiencies related to patient treatment. Importantly, the biological regulation of both hematopoiesis and PSCs has been experimentally confirmed to significantly deviate between humans and other animals, such as mice, further reinforcing the importance of human-specific cell models of hematopoiesis. Therefore, I hypothesized that human stem cell models provide a focused approach to interrogate the regulation of hematopoiesis from the apex of the hierarchy, which can be used to understand the promotion of healthy hematopoiesis and understand malignant transformation. Collectively, the data presented within this thesis offer a deeper conceptualization of human stem cell models and the deconvolution of several complex components of hematopoietic regulation. This work has revealed novel, clinically relevant, and actionable targets to ultimately enable the promotion of healthy hematopoiesis on multiple fronts. / Thesis / Doctor of Philosophy (PhD) / This thesis presents research on novel molecular and genetic regulatory pathways of self-renewal and differentiation in models of healthy and malignant human hematopoiesis. The origin of healthy hematopoietic regulation stems from a large body of work spanning decades and encompasses many efforts by others to derive hematopoietic stem cells from human pluripotent cells. The development of a genetic model for the malignant regulation of CLL was truly serendipitous, was propelled through robust and intriguing results that begged for further exploration, and filled a clinical gap in identifying actionable targets in CLL. Lastly, these two projects, along with my supportive roles in other published works throughout my graduate studies, instructed me to develop a human-mouse transplant model to uncover the biology of regenerating healthy hematopoiesis during injury.

hematopoiesis

pluripotent stem cells

chronic lymphocytic leukemia

chemotherapy-induced myelosuppression

patient derived xenograft model

trisomy 12

Fusion of bovine fibroblasts to mouse embryonic stem cells: a model to study nuclear reprogramming

Villafranca Locher, Maria Cristina

20 April 2018

The cells from the inner cell mass (ICM) of an early embryo have the potential to differentiate into all the different cell types present in an adult organism. Cells from the ICM can be isolated and cultured in vitro, becoming embryonic stem cells (ESCs). ESCs have several properties that make them unique: they are unspecialized, can self-renew indefinitely in culture, and given the appropriate cues can differentiate into cells from all three germ layers (ecto-, meso-, and endoderm), including the germline, both in vivo and in vitro. Induced pluripotent stem cells (iPSCs) can be generated from adult, terminally differentiated somatic cells by transient exogenous expression of four transcription factors (Oct4, Sox2, Klf4, and cMyc; OSKM) present normally in ESCs. It has been shown that iPSCs are equivalent to ESCs in terms of morphology, gene expression, epigenetic signatures, in vitro proliferation capacity, and in vitro and in vivo differentiation potential. However, unlike ESCs, iPSCs can be obtained from a specific individual without the need for embryos. This makes them a promising source of pluripotent cells for regenerative medicine, tissue engineering, drug discovery, and disease modelling; additionally, in livestock species such as the bovine, they also have applications in genetic selection, production of transgenic animals for agricultural and biomedical purposes, and species conservancy. Nevertheless, ESC and iPSC lines that meet all pluripotency criteria have, to date, only been successfully produced in mice, rats, humans, and non-human primates. In the first part of this dissertation, we attempted reprogramming of three types of bovine somatic cells: fetal fibroblasts (bFFs), adult fibroblasts (bAFs), and bone marrow-derived mesenchymal stem cells (bMSCs), using six different culture conditions adapted from recent work in mice and humans. Using basic mouse reprogramming conditions, we did not succeed in inducing formation of ESC-like colonies in bovine somatic cells. The combination of 2i/LIF plus ALK5 inhibitor II and ascorbic acid, induced formation of colony-like structures with flat morphology, that occasionally produced trophoblast-like structures. These trophoblast-like vesicles did not appear when an inhibitor of Rho-associated, coiled-coil containing protein kinase 1 (ROCK) was included in the medium. We screened for expression of exogenous OSKM vector with RT-PCR and found upregulation of OSKM vector 24h after Dox was added to the medium; however, expression was sharply decreased on day 2 after Dox induction, and was not detectable after day 3. In a separate experiment, we induced reprogramming of bFF and bAFs using medium supplemented with 50% of medium conditioned by co-culture with the bovine trophoblast CT1 line. These cells expressed both OCT4 and the OSKM vector 24h after Dox induction. However, similar to our previous observations, both markers decreased expression until no signal was detected after day 3. In summary, we were unable to produce fully reprogrammed bovine iPSCs using mouse and human protocols, and the exact cause of our lack of success is unclear. It is possible that a different method of transgene expression could play a role in reprogramming. However, these ideas would be driven by a rather empirical reasoning, extrapolating findings from other species, and not contributing in our understanding of the particular differences of pluripotecy in ungulates. Our inability to produce bovine iPSCs, combined with the only partial reprogramming observed by others, justifies the need for in depth study of bovine pluripotency mechanisms, before meaningful attempts to reprogram bovine somatic cells to plutipotency are made. Therefore, we focused on getting a better understanding of bovine nuclear reprogramming. This would allow us to rationally target the specific requirements of potential bovine pluripotent cells. Cell fusion is a process that involves fusion of the membrane of two or more cells to form a multinucleated cell. Fusion of a somatic cell to an ESC is known to induce expression of pluripotency markers in the somatic nucleus. In the second part of this dissertation, we hypothesized that fusion of bFFs to mouse ESCs (mESCs) would induce expression of pluripotency markers in the bFF nucleus. We first optimized a cell fusion protocol based on the use of polyethylene glycol (PEG), and obtained up to 11.02% of multinucleated cells in bFFs. Next, we established a method to specifically select for multinucleated cells originated from the fusion of mESCs with bFFs (heterokaryons), using indirect immunofluorescence. With this in place, flow cytometry was used to select 200 heterokaryons which were further analyzed using RNA-seq. We found changes in bovine gene expression patterns between bFFs and heterokaryons obtained 24h after fusion. Focusing on the bovine transcriptome, heterokaryons presented upregulation of early pluripotency markers OCT4 and KLF4, as well as hypoxia response genes, contrasted with downregulation of cell cycle inhibitors such as SST. The cytokine IL6, known to increase survival of early embryos in vitro, was upregulated in heterokaryons, although its role and mechanism of action is still unclear. This indicates that the heterokaryon cell fusion model recapitulates several of the events of early reprogramming, and can therefore be used for further study of pluripotency in the bovine. The cell fusion model presented here can be used as a tool to characterize early changes in bovine somatic nuclear reprogramming, and to study the effect of different reprogramming conditions on the bovine transcriptome. / Ph. D. / The cells of an early embryo have the potential to give rise to any cell type found in the adult body. When these cells are transferred to a culture dish and kept under the right conditions, they become Embryonic Stem Cells (ESCs), and they retain the same developmental potential as the original embryonic cells they were derived from. In 2006, researchers in Japan found that it is possible to “reprogram” the cells of an adult individual (for example, fibroblast skin cells taken from a biopsy) to an embryonic state, by forcing the cells to express extra copies of genes that are normally active in embryos. These reprogrammed cells are called induced Pluripotent Stem Cells (iPSCs), and similarly to ESCs, they also have the potential to produce any cell type found in an adult organism. Lines of iPSCs from livestock species have possible applications in agriculture, species conservancy, biomedical industry, and veterinary and human health. Unfortunately, for reasons that are to date not fully understood, the technology to produce iPSCs has, so far, only worked in mice, rats, humans, and non-human primates. We first attempted to produce bovine iPSCs by adapting methods and conditions used to derive iPSCs in mice and humans. We observed partial reprogramming of bovine cells, but were ultimately not able to produce true bovine iPSCs. This suggests that the bovine requires alternative/additional factors to induce reprogramming in adult cells. However, not knowing exactly what conditions or reagents will induce the reprogramming process in the cow, we decided to take a different approach. We focused on trying to understand how nuclear reprogramming works in the bovine. This would allow us to rationally target the specific requirements of potential bovine pluripotent cells. It is known that the fusion (“merging”) of an adult cell with a stem cell, causes the adult cell to change its gene expression pattern to resemble a stem cell. We therefore fused mouse ESCs with bovine fibroblasts, and observed changes in bovine gene expression pattern as early as 24 hours after fusion. The gene expression changes observed resemble those found during early reprogramming of human and mouse iPSCs, and are accompanied by silencing of fibroblast specific genes. This suggests that our cell fusion model recreates the changes that happen during reprogramming, and can therefore be used as a tool to better understand pluripotency in the cow. The cell fusion method described in this dissertation can in theory be adapted to other species; by fusing somatic cells from other species to mouse ESCs, this model can be used to find species specific relevant pluripotency genes.

somatic cell nuclear reprogramming

pluripotency

induced pluripotent stem cells

cell fusion

Bos taurus

Mus musculus

Development of induced pluripotent Stem cells from human blood mononuclear cells for skin organoid development

Cervone-Maffa III, Francis J.

31 October 2024

Mosquito-borne viruses (MBV) are the cause of significant health and economic concerns worldwide. However, the mechanisms by which these viruses are transmitted to humans remain elusive. This is due to the scarcity of animal models recapitulating mosquitoes to human MBV transmission. While transgenic mice defective in their immune responses are permissive to MBV infection, the partial immunodeficiency of these models and the lack of human skin preclude an accurate understanding of the molecular and cellular mechanisms driving effective MBV transmission. The goal of this project is to develop the first mouse model co-engrafted with a functional human immune system and syngeneic induced pluripotent stem cells (iPSC)-derived skin organoids. This novel mouse model will illuminate critical mechanisms and host-pathogen interactions driving MBV transmission and provide a novel technology to model skin-related diseases. / 2026-10-31T00:00:00Z

Virology

Flavivirus

Human immune system

Human induced pluripotent stem cells

Mouse model

Skin

Skin organoids