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2. Investigating the role of cell cycle regulators in mesoderm specification

Author

Yiangou, Loukia, Sinha, Sanjay, and Vallier, Ludovic

Subjects
616.02, stem cells, mesoderm, cell cycle
Abstract

Mesoderm is one of the three primary germ layers from which the cardiovascular system, muscle and bone originate and derivatives of the mesoderm lineage are affected in a number of pathologies. Therefore, understanding the mechanisms regulating formation of mesoderm is interesting for a diversity of diseases and clinical application. In vivo study of human development beyond gastrulation is technically challenging and the mechanisms controlling mesoderm specification are difficult to study since the maximum number of days allowed to grow human embryos is 14 days. Thus, in this dissertation I use human pluripotent stem cells (hPSCs) as a simplified model of human development. Studies have shown that the cell cycle machinery plays a direct role in the differentiation of endoderm and ectoderm lineages but its role in guiding mesoderm subtype formation remains elusive. In this dissertation, I provide new insights of the importance of the cell cycle regulators in mesoderm specification. I first developed tools such as the FUCCI2A reporter line to isolate cells in the different cell cycle phases and to investigate propensity of mesoderm differentiation. I have shown that the propensity of differentiation into the three mesoderm subtypes lateral plate mesoderm, cardiac mesoderm and presomitic mesoderm varies during the cell cycle phases, with differentiation being more efficient in the G1 and to a lesser extend in G2/M phase. Furthermore, I developed a protocol where cells can be efficiently synchronised in the different cell cycle phases using the G2/M inhibitor nocodazole. Using this tool, I showed that developmental signalling pathways such as BMP and WNT are active in all cell cycle phases indicating that alternative mechanisms are involved in the differentiation process. In order to further explore these mechanisms, I investigated the role of cell cycle regulators controlling the G1 and G2 checkpoint. I have shown that the cell cycle regulators CDK4/6, CDK2, Retinoblastoma phosphorylation and CDK1 are essential for mesoderm subtype formation. Furthermore, I have shown that CDK1 regulates the activity of ERK1/2 signalling, an important pathway for the differentiation process confirming the existence of complex interplays between cell cycle machinery, signalling pathways and transcription factors in mesoderm subtype formation. This knowledge will be useful to further improve protocols for generating mesoderm subtypes from hPSCs for clinical applications such as drug screening, disease modelling and cell based therapy.

Published
2018
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5. Chronic Mexiletine Administration Increases Sodium Current in Non-Diseased Human Induced Pluripotent Stem Cell-Derived Cardiomyocytes.

Author

Nasilli, Giovanna, Verkerk, Arie O., O'Reilly, Molly, Yiangou, Loukia, Davis, Richard P., Casini, Simona, and Remme, Carol Ann

Subjects
MEXILETINE, ACTION potentials, SODIUM channels, SODIUM channel blockers, SODIUM
Abstract

A sodium current (INa) reduction occurs in the setting of many acquired and inherited conditions and is associated with cardiac conduction slowing and increased arrhythmia risks. The sodium channel blocker mexiletine has been shown to restore the trafficking of mutant sodium channels to the membrane. However, these studies were mostly performed in heterologous expression systems using high mexiletine concentrations. Moreover, the chronic effects on INa in a non-diseased cardiomyocyte environment remain unknown. In this paper, we investigated the chronic and acute effects of a therapeutic dose of mexiletine on INa and the action potential (AP) characteristics in human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) of a healthy individual. Control hiPSC-CMs were incubated for 48 h with 10 µM mexiletine or vehicle. Following the wash-out of mexiletine, patch clamp analysis and immunocytochemistry experiments were performed. The incubation of hiPSC-CMs for 48 h with mexiletine (followed by wash-out) induced a significant increase in peak INa of ~75%, without any significant change in the voltage dependence of (in)activation. This was accompanied by a significant increase in AP upstroke velocity, without changes in other AP parameters. The immunocytochemistry experiments showed a significant increase in membrane Nav1.5 fluorescence following a 48 h incubation with mexiletine. The acute re-exposure of hiPSC-CMs to 10 µM mexiletine resulted in a small but significant increase in AP duration, without changes in AP upstroke velocity, peak INa density, or the INa voltage dependence of (in)activation. Importantly, the increase in the peak INa density and resulting AP upstroke velocity induced by chronic mexiletine incubation was not counteracted by the acute re-administration of the drug. In conclusion, the chronic administration of a clinically relevant concentration of mexiletine increases INa density in non-diseased hiPSC-CMs, likely by enhancing the membrane trafficking of sodium channels. Our findings identify mexiletine as a potential therapeutic strategy to enhance and/or restore INa and cardiac conduction. [ABSTRACT FROM AUTHOR]

Published
2024
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11. Optogenetic Reporters Delivered as mRNA Facilitate Repeatable Action Potential and Calcium Handling Assessment in Human iPSC-Derived Cardiomyocytes

Author

Yiangou, Loukia, primary, Blanch-Asensio, Albert, additional, de Korte, Tessa, additional, Miller, Duncan C, additional, van Meer, Berend J, additional, Mol, Mervyn P H, additional, van den Brink, Lettine, additional, Brandão, Karina O, additional, Mummery, Christine L, additional, and Davis, Richard P, additional

Published
2022
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12. Maturation of hiPSC-derived cardiomyocytes promotes adult alternative splicing of SCN5A and reveals changes in sodium current associated with cardiac arrhythmia

Author

Campostrini, Giulia, primary, Kosmidis, Georgios, additional, Ward-van Oostwaard, Dorien, additional, Davis, Richard Paul, additional, Yiangou, Loukia, additional, Ottaviani, Daniele, additional, Veerman, Christiaan Cornelis, additional, Mei, Hailiang, additional, Orlova, Valeria Viktorovna, additional, Wilde, Arthur Arnold Maria, additional, Bezzina, Connie Rose, additional, Verkerk, Arie Otto, additional, Mummery, Christine Lindsay, additional, and Bellin, Milena, additional

Published
2022
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15. Maturation of hiPSC-derived cardiomyocytes promotes adult alternative splicing of SCN5A and reveals changes in sodium current associated with cardiac arrhythmia.

Author

Campostrini, Giulia, Kosmidis, Georgios, Oostwaard, Dorien Ward-van, Davis, Richard Paul, Yiangou, Loukia, Ottaviani, Daniele, Veerman, Christiaan Cornelis, Mei, Hailiang, Orlova, Valeria Viktorovna, Wilde, Arthur Arnold Maria, Bezzina, Connie Rose, Verkerk, Arie Otto, Mummery, Christine Lindsay, and Bellin, Milena

Subjects
ALTERNATIVE RNA splicing, ARRHYTHMIA, SODIUM channels, GENETIC variation, ION channels, ADULTS
Abstract

Aims Human-induced pluripotent stem cell-cardiomyocytes (hiPSC-CMs) are widely used to study arrhythmia-associated mutations in ion channels. Among these, the cardiac sodium channel SCN5A undergoes foetal-to-adult isoform switching around birth. Conventional hiPSC-CM cultures, which are phenotypically foetal, have thus far been unable to capture mutations in adult gene isoforms. Here, we investigated whether tri-cellular cross-talk in a three-dimensional (3D) cardiac microtissue (MT) promoted post-natal SCN5A maturation in hiPSC-CMs. Methods and results We derived patient hiPSC-CMs carrying compound mutations in the adult SCN5A exon 6B and exon 4. Electrophysiological properties of patient hiPSC-CMs in monolayer were not altered by the exon 6B mutation compared with isogenic controls since it is not expressed; further, CRISPR/Cas9-mediated excision of the foetal exon 6A did not promote adult SCN5A expression. However, when hiPSC-CMs were matured in 3D cardiac MTs, SCN5A underwent isoform switch and the functional consequences of the mutation located in exon 6B were revealed. Up-regulation of the splicing factor muscleblind-like protein 1 (MBNL1) drove SCN5A post-natal maturation in microtissues since its overexpression in hiPSC-CMs was sufficient to promote exon 6B inclusion, whilst knocking-out MBNL1 failed to foster isoform switch. Conclusions Our study shows that (i) the tri-cellular cardiac microtissues promote post-natal SCN5A isoform switch in hiPSC-CMs, (ii) adult splicing of SCN5A is driven by MBNL1 in these tissues, and (iii) this model can be used for examining post-natal cardiac arrhythmias due to mutations in the exon 6B. Translational perspective The cardiac sodium channel is essential for conducting the electrical impulse in the heart. Postnatal alternative splicing regulation causes mutual exclusive inclusion of fetal or adult exons of the corresponding gene, SCN5A. Typically, immature hiPSCCMs fall short in studying the effect of mutations located in the adult exon. We describe here that an innovative tri-cellular three-dimensional cardiac microtissue culture promotes hiPSC-CMs maturation through upregulation of MBNL1, thus revealing the effect of a pathogenic genetic variant located in the SCN5A adult exon. These results help advancing the use of hiPSC-CMs in studying adult heart disease and for developing personalized medicine applications. [ABSTRACT FROM AUTHOR]

Published
2023
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16. The SMAD2/3 interactome reveals that TGF controls m6A mRNA methylation in pluripotency

Author

Bertero, Alessandro, Brown, Stephanie, Madrigal, Pedro, Osnato, Anna, Ortmann, Daniel, Yiangou, Loukia, Kadiwala, Juned, Hubner, Nina C., de los Mozos, Igor Ruiz, Sade, Christoph, Lenaerts, An-Sofie, Nakanoh, Shota, Grandy, Rodrigo, Farnell, Edward, Ule, Jernej, Stunnenberg, Hendrik G., Mendjan, Sasha, and Vallier, Ludovic

Subjects
Smad proteins -- Genetic aspects -- Physiological aspects, Physiological research, Transforming growth factors -- Genetic aspects, Methylation -- Research, Messenger RNA -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Alessandro Bertero [1]; Stephanie Brown [1]; Pedro Madrigal [1, 2]; Anna Osnato [1]; Daniel Ortmann [1]; Loukia Yiangou [1]; Juned Kadiwala [1]; Nina C. Hubner [3]; Igor Ruiz de [...]

Published
2018
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19. Method to Synchronize Cell Cycle of Human Pluripotent Stem Cells without Affecting Their Fundamental Characteristics

Author

Yiangou, Loukia, primary, Grandy, Rodrigo A., additional, Morell, Carola M., additional, Tomaz, Rute A., additional, Osnato, Anna, additional, Kadiwala, Juned, additional, Muraro, Daniele, additional, Garcia-Bernardo, Jose, additional, Nakanoh, Shota, additional, Bernard, William G., additional, Ortmann, Daniel, additional, McCarthy, Davis J., additional, Simonic, Ingrid, additional, Sinha, Sanjay, additional, and Vallier, Ludovic, additional

Published
2019
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20. The SMAD2/3 interactome reveals that TGF beta controls m(6)A mRNA methylation in pluripotency

Author

Bertero, A., Brown, S., Madrigal, P., Osnato, Anna, Ortmann, Daniel, Yiangou, Loukia, Hubner, N.C., Stunnenberg, Hendrik G., Mendjan, S., Vallier, L., Bertero, A., Brown, S., Madrigal, P., Osnato, Anna, Ortmann, Daniel, Yiangou, Loukia, Hubner, N.C., Stunnenberg, Hendrik G., Mendjan, S., and Vallier, L.

Abstract

Contains fulltext : 235975.pdf (Publisher’s version ) (Closed access)

Published
2018

21. Reconstruction of the mouse extrahepatic biliary tree using primary human extrahepatic cholangiocyte organoids

Author

Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, and Vallier, Ludovic

Subjects
Cholangiocytes, Bile duct, Bio-engineering, Tissue engineering, Organoids, Regenerative medicine, Cell-based therapy, Biliary atresia, PGA scaffold, Collagen scaffold, Densified collagen
Abstract

© 2017 Nature America, Inc., part of Springer Nature. All rights reserved. The treatment of common bile duct (CBD) disorders, such as biliary atresia or ischemic strictures, is restricted by the lack of biliary tissue from healthy donors suitable for surgical reconstruction. Here we report a new method for the isolation and propagation of human cholangiocytes from the extrahepatic biliary tree in the form of extrahepatic cholangiocyte organoids (ECOs) for regenerative medicine applications. The resulting ECOs closely resemble primary cholangiocytes in terms of their transcriptomic profile and functional properties. We explore the regenerative potential of these organoids in vivo and demonstrate that ECOs self-organize into bile duct-like tubes expressing biliary markers following transplantation under the kidney capsule of immunocompromised mice. In addition, when seeded on biodegradable scaffolds, ECOs form tissue-like structures retaining biliary characteristics. The resulting bioengineered tissue can reconstruct the gallbladder wall and repair the biliary epithelium following transplantation into a mouse model of injury. Furthermore, bioengineered artificial ducts can replace the native CBD, with no evidence of cholestasis or occlusion of the lumen. In conclusion, ECOs can successfully reconstruct the biliary tree, providing proof of principle for organ regeneration using human primary cholangiocytes expanded in vitro.

Published
2017

22. Optimized inducible shRNA and CRISPR/Cas9 platforms for in vitro studies of human development using hPSCs

Author

Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Sinha, Sanjay, Kotter, Mark, and Vallier, Ludovic

Subjects
Human pluripotent stem cells, shRNA, CRISPR/Cas9,OCT4, POU5F1, T, brachyury, DPY30
Abstract

© 2016. Inducible loss of gene function experiments are necessary to uncover mechanisms underlying development, physiology and disease. However, current methods are complex, lack robustness and do not work in multiple cell types. Here we address these limitations by developing single-step optimized inducible gene knockdown or knockout (sOPTiKD or sOPTiKO) platforms. These are based on genetic engineering of human genomic safe harbors combined with an improved tetracycline-inducible system and CRISPR/Cas9 technology. We exemplify the efficacy of these methods in human pluripotent stem cells (hPSCs), and show that generation of sOPTiKD/KO hPSCs is simple, rapid and allows tightly controlled individual or multiplexed gene knockdown or knockout in hPSCs and in a wide variety of differentiated cells. Finally, we illustrate the general applicability of this approach by investigating the function of transcription factors (OCT4 and T), cell cycle regulators (cyclin D family members) and epigenetic modifiers (DPY30). Overall, sOPTiKD and sOPTiKO provide a unique opportunity for functional analyses in multiple cell types relevant for the study of human development.

Published
2016

25. Early loss of Crebbp confers malignant stem cell properties on lymphoid progenitors

Author

Horton, Sarah J., primary, Giotopoulos, George, additional, Yun, Haiyang, additional, Vohra, Shabana, additional, Sheppard, Olivia, additional, Bashford-Rogers, Rachael, additional, Rashid, Mamunur, additional, Clipson, Alexandra, additional, Chan, Wai-In, additional, Sasca, Daniel, additional, Yiangou, Loukia, additional, Osaki, Hikari, additional, Basheer, Faisal, additional, Gallipoli, Paolo, additional, Burrows, Natalie, additional, Erdem, Ayşegül, additional, Sybirna, Anastasiya, additional, Foerster, Sarah, additional, Zhao, Wanfeng, additional, Sustic, Tonci, additional, Petrunkina Harrison, Anna, additional, Laurenti, Elisa, additional, Okosun, Jessica, additional, Hodson, Daniel, additional, Wright, Penny, additional, Smith, Ken G., additional, Maxwell, Patrick, additional, Fitzgibbon, Jude, additional, Du, Ming Q., additional, Adams, David J., additional, and Huntly, Brian J. P., additional

Published
2017
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26. A Stem Cell Strategy Identifies Glycophorin C as a Major Erythrocyte Receptor for the Rodent Malaria Parasite Plasmodium berghei

Author

Yiangou, Loukia, Montandon, Ruddy, Modrzynska, Katarzyna, Rosen, Barry, Bushell, Wendy, Hale, Christine, Billker, Oliver, Rayner, Julian C., Pance, Alena, Yiangou, Loukia, Montandon, Ruddy, Modrzynska, Katarzyna, Rosen, Barry, Bushell, Wendy, Hale, Christine, Billker, Oliver, Rayner, Julian C., and Pance, Alena

Abstract

The clinical complications of malaria are caused by the parasite expansion in the blood. Invasion of erythrocytes is a complex process that depends on multiple receptor-ligand interactions. Identification of host receptors is paramount for fighting the disease as it could reveal new intervention targets, but the enucleated nature of erythrocytes makes genetic approaches impossible and many receptors remain unknown. Host-parasite interactions evolve rapidly and are therefore likely to be species-specific. As a results, understanding of invasion receptors outside the major human pathogen Plasmodium falciparum is very limited. Here we use mouse embryonic stem cells (mESCs) that can be genetically engineered and differentiated into erythrocytes to identify receptors for the rodent malaria parasite Plasmodium berghei. Two proteins previously implicated in human malaria infection: glycophorin C (GYPC) and Band-3 (Slc4a1) were deleted in mESCs to generate stable cell lines, which were differentiated towards erythropoiesis. In vitro infection assays revealed that while deletion of Band-3 has no effect, absence of GYPC results in a dramatic decrease in invasion, demonstrating the crucial role of this protein for P. berghei infection. This stem cell approach offers the possibility of targeting genes that may be essential and therefore difficult to disrupt in whole organisms and has the potential to be applied to a variety of parasites in diverse host cell types.

Published
2016
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28. The SMAD2/3 interactome reveals that TGFβ controls m6A mRNA methylation in pluripotency.

Author

Bertero, Alessandro, Brown, Stephanie, Madrigal, Pedro, Osnato, Anna, Ortmann, Daniel, Yiangou, Loukia, Kadiwala, Juned, Hubner, Nina C., de los Mozos, Igor Ruiz, Sadée, Christoph, Lenaerts, An-Sofie, Nakanoh, Shota, Grandy, Rodrigo, Farnell, Edward, Ule, Jernej, Stunnenberg, Hendrik G., Mendjan, Sasha, and Vallier, Ludovic

Abstract

The TGFβ pathway has essential roles in embryonic development, organ homeostasis, tissue repair and disease. These diverse effects are mediated through the intracellular effectors SMAD2 and SMAD3 (hereafter SMAD2/3), whose canonical function is to control the activity of target genes by interacting with transcriptional regulators. Therefore, a complete description of the factors that interact with SMAD2/3 in a given cell type would have broad implications for many areas of cell biology. Here we describe the interactome of SMAD2/3 in human pluripotent stem cells. This analysis reveals that SMAD2/3 is involved in multiple molecular processes in addition to its role in transcription. In particular, we identify a functional interaction with the METTL3-METTL14-WTAP complex, which mediates the conversion of adenosine to N6-methyladenosine (m6A) on RNA. We show that SMAD2/3 promotes binding of the m6A methyltransferase complex to a subset of transcripts involved in early cell fate decisions. This mechanism destabilizes specific SMAD2/3 transcriptional targets, including the pluripotency factor gene NANOG, priming them for rapid downregulation upon differentiation to enable timely exit from pluripotency. Collectively, these findings reveal the mechanism by which extracellular signalling can induce rapid cellular responses through regulation of the epitranscriptome. These aspects of TGFβ signalling could have far-reaching implications in many other cell types and in diseases such as cancer. [ABSTRACT FROM AUTHOR]

Published
2018
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29. Early loss of Crebbp confers malignant stem cell properties on lymphoid progenitors

Author

Horton, Sarah J, Giotopoulos, George, Yun, Haiyang, Vohra, Shabana, Sheppard, Olivia, Bashford-Rogers, Rachael, Rashid, Mamunur, Clipson, Alexandra, Chan, Wai-In, Sasca, Daniel, Yiangou, Loukia, Osaki, Hikari, Basheer, Faisal, Gallipoli, Paolo, Burrows, Natalie, Erdem, Ayşegül, Sybirna, Anastasiya, Foerster, Sarah, Zhao, Wanfeng, Sustic, Tonci, Petrunkina Harrison, Anna, Laurenti, Elisa, Okosun, Jessica, Hodson, Daniel, Wright, Penny, Smith, Ken G, Maxwell, Patrick, Fitzgibbon, Jude, Du, Ming Q, Adams, David J, and Huntly, Brian JP

Subjects
Time Factors, Lymphoma, Transcription, Genetic, Methylation, Epigenesis, Genetic, Histones, Mice, Animals, Genetic Predisposition to Disease, Cell Self Renewal, Lymphangiogenesis, Cells, Cultured, Cell Proliferation, Mice, Knockout, Lymphopoiesis, Acetylation, Lymphoid Progenitor Cells, CREB-Binding Protein, 3. Good health, Gene Expression Regulation, Neoplastic, Mice, Inbred C57BL, Cell Transformation, Neoplastic, Phenotype, Mutation, Neoplastic Stem Cells, Tumor Suppressor Protein p53, DNA Damage, Signal Transduction
Abstract

Loss-of-function mutations of cyclic-AMP response element binding protein, binding protein (CREBBP) are prevalent in lymphoid malignancies. However, the tumour suppressor functions of CREBBP remain unclear. We demonstrate that loss of Crebbp in murine haematopoietic stem and progenitor cells (HSPCs) leads to increased development of B-cell lymphomas. This is preceded by accumulation of hyperproliferative lymphoid progenitors with a defective DNA damage response (DDR) due to a failure to acetylate p53. We identify a premalignant lymphoma stem cell population with decreased H3K27ac, which undergoes transcriptional and genetic evolution due to the altered DDR, resulting in lymphomagenesis. Importantly, when Crebbp is lost later in lymphopoiesis, cellular abnormalities are lost and tumour generation is attenuated. We also document that CREBBP mutations may occur in HSPCs from patients with CREBBP-mutated lymphoma. These data suggest that earlier loss of Crebbp is advantageous for lymphoid transformation and inform the cellular origins and subsequent evolution of lymphoid malignancies.

30. Method to Synchronize Cell Cycle of Human Pluripotent Stem Cells without Affecting Their Fundamental Characteristics

Author

Yiangou, Loukia, Grandy, Rodrigo A, Morell, Carola M, Tomaz, Rute A, Osnato, Anna, Kadiwala, Juned, Muraro, Daniele, Garcia-Bernardo, Jose, Nakanoh, Shota, Bernard, William G, Ortmann, Daniel, McCarthy, Davis J, Simonic, Ingrid, Sinha, Sanjay, and Vallier, Ludovic

Subjects
single-cell RNA-seq, Nocodazole, cell cycle synchronization, Cell Cycle, Endoderm, Human Embryonic Stem Cells, Karyotype, Cell Differentiation, Tubulin Modulators, 3. Good health, Cell Line, ectoderm, mesoderm, Humans, Cellular Reprogramming Techniques, Transcriptome, hPSCs
Abstract

Cell cycle progression and cell fate decisions are closely linked in human pluripotent stem cells (hPSCs). However, the study of these interplays at the molecular level remains challenging due to the lack of efficient methods allowing cell cycle synchronization of large quantities of cells. Here, we screened inhibitors of cell cycle progression and identified nocodazole as the most efficient small molecule to synchronize hPSCs in the G2/M phase. Following nocodazole treatment, hPSCs remain pluripotent, retain a normal karyotype and can successfully differentiate into the three germ layers and functional cell types. Moreover, genome-wide transcriptomic analyses on single cells synchronized for their cell cycle and differentiated toward the endoderm lineage validated our findings and showed that nocodazole treatment has no effect on gene expression during the differentiation process. Thus, our synchronization method provides a robust approach to study cell cycle mechanisms in hPSCs.

31. Human Pluripotent Stem Cell-Derived Endoderm for Modeling Development and Clinical Applications

Author

Yiangou, Loukia, Ross, Alexander DB, Goh, Kim Jee, and Vallier, Ludovic

Subjects
Pluripotent Stem Cells, embryonic structures, disease modeling, Endoderm, gut, Humans, human pluripotent stem cells, pancreas, liver, Models, Biological, lungs, 3. Good health
Abstract

The liver, lung, pancreas, and digestive tract all originate from the endoderm germ layer, and these vital organs are subject to many life-threatening diseases affecting millions of patients. However, primary cells from endodermal organs are often difficult to grow in vitro. Human pluripotent stem cells thus hold great promise for generating endoderm cells and their derivatives as tools for the development of new therapeutics against a variety of global healthcare challenges. Here we describe recent advances in methods for generating endodermal cell types from human pluripotent stem cells and their use for disease modeling and cell-based therapy.

32. The SMAD2/3 interactome reveals that TGFβ controls m6A mRNA methylation in pluripotency

Author

Bertero, Alessandro, Brown, Stephanie, Madrigal, Pedro, Osnato, Anna, Ortmann, Daniel, Yiangou, Loukia, Kadiwala, Juned, Hubner, Nina C, De Los Mozos, Igor Ruiz, Sadée, Christoph, Lenaerts, An-Sofie, Nakanoh, Shota, Grandy, Rodrigo, Farnell, Edward, Ule, Jernej, Stunnenberg, Hendrik G, Mendjan, Sasha, and Vallier, Ludovic

Subjects
Pluripotent Stem Cells, Adenosine, Nodal Protein, Nuclear Proteins, Cell Cycle Proteins, Cell Differentiation, Methyltransferases, Nanog Homeobox Protein, Smad2 Protein, Methylation, 3. Good health, Activins, Epigenesis, Genetic, Transforming Growth Factor beta, Multiprotein Complexes, Animals, Humans, RNA Splicing Factors, RNA, Messenger, Smad3 Protein, Transcriptome, Protein Binding, Signal Transduction
Abstract

The TGFβ pathway has essential roles in embryonic development, organ homeostasis, tissue repair and disease. These diverse effects are mediated through the intracellular effectors SMAD2 and SMAD3 (hereafter SMAD2/3), whose canonical function is to control the activity of target genes by interacting with transcriptional regulators. Therefore, a complete description of the factors that interact with SMAD2/3 in a given cell type would have broad implications for many areas of cell biology. Here we describe the interactome of SMAD2/3 in human pluripotent stem cells. This analysis reveals that SMAD2/3 is involved in multiple molecular processes in addition to its role in transcription. In particular, we identify a functional interaction with the METTL3-METTL14-WTAP complex, which mediates the conversion of adenosine to N6-methyladenosine (m6A) on RNA. We show that SMAD2/3 promotes binding of the m6A methyltransferase complex to a subset of transcripts involved in early cell fate decisions. This mechanism destabilizes specific SMAD2/3 transcriptional targets, including the pluripotency factor gene NANOG, priming them for rapid downregulation upon differentiation to enable timely exit from pluripotency. Collectively, these findings reveal the mechanism by which extracellular signalling can induce rapid cellular responses through regulation of the epitranscriptome. These aspects of TGFβ signalling could have far-reaching implications in many other cell types and in diseases such as cancer.

33. Cell cycle regulators control mesoderm specification in human pluripotent stem cells

Author

Yiangou, Loukia, Grandy, Rodrigo A, Osnato, Anna, Ortmann, Daniel, Sinha, Sanjay, and Vallier, Ludovic

Subjects
animal structures, MAP Kinase Signaling System, Ubiquitin-Protein Ligases, Cell Cycle, Human Embryonic Stem Cells, embryo development, Cell Differentiation, RB transcriptional corepressor 1 (RB1), differentiation, tissue regeneration, cyclin-dependent kinase (CDK), pluripotency, Cyclin-Dependent Kinases, 3. Good health, Mesoderm, Retinoblastoma Binding Proteins, stem cells, embryonic structures, gene expression, Humans, Cell Lineage, signaling, Protein Kinase Inhibitors
Abstract

The mesoderm is one of the three germ layers produced during gastrulation from which muscle, bones, kidneys, and the cardiovascular system originate. Understanding the mechanisms that control mesoderm specification could inform many applications, including the development of regenerative medicine therapies to manage diseases affecting these tissues. Here, we used human pluripotent stem cells to investigate the role of cell cycle in mesoderm formation. To this end, using small molecules or conditional gene knockdown, we inhibited proteins controlling G1 and G2/M cell cycle phases during the differentiation of human pluripotent stem cells into lateral plate, cardiac, and presomitic mesoderm. These loss-of-function experiments revealed that regulators of the G1 phase, such as cyclin-dependent kinases and pRb (retinoblastoma protein), are necessary for efficient mesoderm formation in a context-dependent manner. Further investigations disclosed that inhibition of the G2/M regulator cyclin-dependent kinase 1 decreases BMP (bone morphogenetic protein) signaling activity specifically during lateral plate mesoderm formation while reducing fibroblast growth factor/extracellular signaling-regulated kinase 1/2 activity in all mesoderm subtypes. Taken together, our findings reveal that cell cycle regulators direct mesoderm formation by controlling the activity of key developmental pathways.

34. Reconstruction of the mouse extrahepatic biliary tree using primary human extrahepatic cholangiocyte organoids

Author

Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, Vallier, Ludovic, Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, and Vallier, Ludovic

Abstract

Treatment of common bile duct disorders such as biliary atresia or ischaemic strictures is limited to liver transplantation or hepatojejunostomy due to the lack of suitable tissue for surgical reconstruction. Here, we report a novel method for the isolation and propagation of human cholangiocytes from the extrahepatic biliary tree and we explore the potential of bioengineered biliary tissue consisting of these extrahepatic cholangiocyte organoids (ECOs) and biodegradable scaffolds for transplantation and biliary reconstruction in vivo. ECOs closely correlate with primary cholangiocytes in terms of transcriptomic profile and functional properties (ALP, GGT). Following transplantation in immunocompromised mice ECOs self-organize into tubular structures expressing biliary markers (CK7). When seeded on biodegradable scaffolds, ECOs form tissue-like structures retaining biliary marker expression (CK7) and function (ALP, GGT). This bioengineered tissue can reconstruct the wall of the biliary tree (gallbladder) and rescue and extrahepatic biliary injury mouse model following transplantation. Furthermore, it can be fashioned into bioengineered ducts and replace the native common bile duct of immunocompromised mice, with no evidence of cholestasis or lumen occlusion up to one month after reconstruction. In conclusion, ECOs can successfully reconstruct the biliary tree following transplantation, providing proof-of-principle for organ regeneration using human primary cells expanded in vitro.

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35. Optimized inducible shRNA and CRISPR/Cas9 platforms for in vitro studies of human development using hPSCs

Author

Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, Vallier, Ludovic, Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, and Vallier, Ludovic

Abstract

Inducible loss of gene function experiments are necessary to uncover mechanisms underlying development, physiology and disease. However, current methods are complex, lack robustness and do not work in multiple cell types. Here we address these limitations by developing single-step optimized inducible gene knockdown or knockout (sOPTiKD or sOPTiKO) platforms. These are based on genetic engineering of human genomic safe harbors combined with an improved tetracycline-inducible system and CRISPR/Cas9 technology. We exemplify the efficacy of these methods in human pluripotent stem cells (hPSCs), and show that generation of sOPTiKD/KO hPSCs is simple, rapid and allows tightly controlled individual or multiplexed gene knockdown or knockout in hPSCs and in a wide variety of differentiated cells. Finally, we illustrate the general applicability of this approach by investigating the function of transcription factors (OCT4 and T), cell cycle regulators (cyclin D family members) and epigenetic modifiers (DPY30). Overall, sOPTiKD and sOPTiKO provide a unique opportunity for functional analyses in multiple cell types relevant for the study of human development.

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36. Reconstruction of the mouse extrahepatic biliary tree using primary human extrahepatic cholangiocyte organoids

Author

Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, Vallier, Ludovic, Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, and Vallier, Ludovic

Abstract

Treatment of common bile duct disorders such as biliary atresia or ischaemic strictures is limited to liver transplantation or hepatojejunostomy due to the lack of suitable tissue for surgical reconstruction. Here, we report a novel method for the isolation and propagation of human cholangiocytes from the extrahepatic biliary tree and we explore the potential of bioengineered biliary tissue consisting of these extrahepatic cholangiocyte organoids (ECOs) and biodegradable scaffolds for transplantation and biliary reconstruction in vivo. ECOs closely correlate with primary cholangiocytes in terms of transcriptomic profile and functional properties (ALP, GGT). Following transplantation in immunocompromised mice ECOs self-organize into tubular structures expressing biliary markers (CK7). When seeded on biodegradable scaffolds, ECOs form tissue-like structures retaining biliary marker expression (CK7) and function (ALP, GGT). This bioengineered tissue can reconstruct the wall of the biliary tree (gallbladder) and rescue and extrahepatic biliary injury mouse model following transplantation. Furthermore, it can be fashioned into bioengineered ducts and replace the native common bile duct of immunocompromised mice, with no evidence of cholestasis or lumen occlusion up to one month after reconstruction. In conclusion, ECOs can successfully reconstruct the biliary tree following transplantation, providing proof-of-principle for organ regeneration using human primary cells expanded in vitro.

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37. Optimized inducible shRNA and CRISPR/Cas9 platforms for in vitro studies of human development using hPSCs

Author

Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, Vallier, Ludovic, Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, and Vallier, Ludovic

Abstract

Inducible loss of gene function experiments are necessary to uncover mechanisms underlying development, physiology and disease. However, current methods are complex, lack robustness and do not work in multiple cell types. Here we address these limitations by developing single-step optimized inducible gene knockdown or knockout (sOPTiKD or sOPTiKO) platforms. These are based on genetic engineering of human genomic safe harbors combined with an improved tetracycline-inducible system and CRISPR/Cas9 technology. We exemplify the efficacy of these methods in human pluripotent stem cells (hPSCs), and show that generation of sOPTiKD/KO hPSCs is simple, rapid and allows tightly controlled individual or multiplexed gene knockdown or knockout in hPSCs and in a wide variety of differentiated cells. Finally, we illustrate the general applicability of this approach by investigating the function of transcription factors (OCT4 and T), cell cycle regulators (cyclin D family members) and epigenetic modifiers (DPY30). Overall, sOPTiKD and sOPTiKO provide a unique opportunity for functional analyses in multiple cell types relevant for the study of human development.

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38. Reconstruction of the mouse extrahepatic biliary tree using primary human extrahepatic cholangiocyte organoids

Author

Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, Vallier, Ludovic, Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, and Vallier, Ludovic

Abstract

Treatment of common bile duct disorders such as biliary atresia or ischaemic strictures is limited to liver transplantation or hepatojejunostomy due to the lack of suitable tissue for surgical reconstruction. Here, we report a novel method for the isolation and propagation of human cholangiocytes from the extrahepatic biliary tree and we explore the potential of bioengineered biliary tissue consisting of these extrahepatic cholangiocyte organoids (ECOs) and biodegradable scaffolds for transplantation and biliary reconstruction in vivo. ECOs closely correlate with primary cholangiocytes in terms of transcriptomic profile and functional properties (ALP, GGT). Following transplantation in immunocompromised mice ECOs self-organize into tubular structures expressing biliary markers (CK7). When seeded on biodegradable scaffolds, ECOs form tissue-like structures retaining biliary marker expression (CK7) and function (ALP, GGT). This bioengineered tissue can reconstruct the wall of the biliary tree (gallbladder) and rescue and extrahepatic biliary injury mouse model following transplantation. Furthermore, it can be fashioned into bioengineered ducts and replace the native common bile duct of immunocompromised mice, with no evidence of cholestasis or lumen occlusion up to one month after reconstruction. In conclusion, ECOs can successfully reconstruct the biliary tree following transplantation, providing proof-of-principle for organ regeneration using human primary cells expanded in vitro.

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39. Optimized inducible shRNA and CRISPR/Cas9 platforms for in vitro studies of human development using hPSCs

Author

Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, Vallier, Ludovic, Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, and Vallier, Ludovic

Abstract

Inducible loss of gene function experiments are necessary to uncover mechanisms underlying development, physiology and disease. However, current methods are complex, lack robustness and do not work in multiple cell types. Here we address these limitations by developing single-step optimized inducible gene knockdown or knockout (sOPTiKD or sOPTiKO) platforms. These are based on genetic engineering of human genomic safe harbors combined with an improved tetracycline-inducible system and CRISPR/Cas9 technology. We exemplify the efficacy of these methods in human pluripotent stem cells (hPSCs), and show that generation of sOPTiKD/KO hPSCs is simple, rapid and allows tightly controlled individual or multiplexed gene knockdown or knockout in hPSCs and in a wide variety of differentiated cells. Finally, we illustrate the general applicability of this approach by investigating the function of transcription factors (OCT4 and T), cell cycle regulators (cyclin D family members) and epigenetic modifiers (DPY30). Overall, sOPTiKD and sOPTiKO provide a unique opportunity for functional analyses in multiple cell types relevant for the study of human development.

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40. Reconstruction of the mouse extrahepatic biliary tree using primary human extrahepatic cholangiocyte organoids

Author

Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, Vallier, Ludovic, Sampaziotis, Fotios, Justin, Alexander W., Tysoe, Olivia C., Sawiak, Stephen, Godfrey, Edmund M., Upponi, Sara S., Gieseck, Richard L., de Brito, Miguel Cardoso, Berntsen, Natalie Lie, Gómez-Vázquez, María J., Ortmann, Daniel, Yiangou, Loukia, Ross, Alexander, Bargehr, Johannes, Bertero, Alessandro, Zonneveld, Mariëlle C.F., Pedersen, Marianne T., Pawlowski, Matthias, Valestrand, Laura, Madrigal, Pedro, Georgakopoulos, Nikitas, Pirmadjid, Negar, Skeldon, Gregor M., Casey, John, Shu, Wenmiao, Materek, Paulina M., Snijders, Kirsten, Brown, Stephanie, Rimland, Casey A., Simonic, Ingrid, Davies, Susan E., Jensen, Kim B., Zilbauer, Matthias, Gelson, William T.H., Alexander, Graeme J., Sinha, Sanjay, Hannan, Nicholas R.F., Wynn, Thomas A., Karlsen, Tom H., Melum, Espen, Markaki, Athina E., Saeb-Parsy, Kourosh, and Vallier, Ludovic

Abstract

Treatment of common bile duct disorders such as biliary atresia or ischaemic strictures is limited to liver transplantation or hepatojejunostomy due to the lack of suitable tissue for surgical reconstruction. Here, we report a novel method for the isolation and propagation of human cholangiocytes from the extrahepatic biliary tree and we explore the potential of bioengineered biliary tissue consisting of these extrahepatic cholangiocyte organoids (ECOs) and biodegradable scaffolds for transplantation and biliary reconstruction in vivo. ECOs closely correlate with primary cholangiocytes in terms of transcriptomic profile and functional properties (ALP, GGT). Following transplantation in immunocompromised mice ECOs self-organize into tubular structures expressing biliary markers (CK7). When seeded on biodegradable scaffolds, ECOs form tissue-like structures retaining biliary marker expression (CK7) and function (ALP, GGT). This bioengineered tissue can reconstruct the wall of the biliary tree (gallbladder) and rescue and extrahepatic biliary injury mouse model following transplantation. Furthermore, it can be fashioned into bioengineered ducts and replace the native common bile duct of immunocompromised mice, with no evidence of cholestasis or lumen occlusion up to one month after reconstruction. In conclusion, ECOs can successfully reconstruct the biliary tree following transplantation, providing proof-of-principle for organ regeneration using human primary cells expanded in vitro.

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41. Optimized inducible shRNA and CRISPR/Cas9 platforms for in vitro studies of human development using hPSCs

Author

Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, Vallier, Ludovic, Bertero, Alessandro, Pawlowski, Matthias, Ortmann, Daniel, Snijders, Kirsten, Yiangou, Loukia, Cardoso de Brito, Miguel, Brown, Stephanie, Bernard, William G., Cooper, James D., Giacomelli, Elisa, Gambardella, Laure, Hannan, Nicholas R.F., Iyer, Dharini, Sampaziotis, Fotios, Serrano, Felipe, Zonneveld, Mariëlle C.F., Sinha, Sanjay, Kotter, Mark, and Vallier, Ludovic

Abstract

Inducible loss of gene function experiments are necessary to uncover mechanisms underlying development, physiology and disease. However, current methods are complex, lack robustness and do not work in multiple cell types. Here we address these limitations by developing single-step optimized inducible gene knockdown or knockout (sOPTiKD or sOPTiKO) platforms. These are based on genetic engineering of human genomic safe harbors combined with an improved tetracycline-inducible system and CRISPR/Cas9 technology. We exemplify the efficacy of these methods in human pluripotent stem cells (hPSCs), and show that generation of sOPTiKD/KO hPSCs is simple, rapid and allows tightly controlled individual or multiplexed gene knockdown or knockout in hPSCs and in a wide variety of differentiated cells. Finally, we illustrate the general applicability of this approach by investigating the function of transcription factors (OCT4 and T), cell cycle regulators (cyclin D family members) and epigenetic modifiers (DPY30). Overall, sOPTiKD and sOPTiKO provide a unique opportunity for functional analyses in multiple cell types relevant for the study of human development.

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42. Cell cycle regulators control mesoderm specification in human pluripotent stem cells

Author

Rodrigo A. Grandy, Loukia Yiangou, Daniel Ortmann, Ludovic Vallier, Anna Osnato, Sanjay Sinha, Yiangou, Loukia [0000-0003-1477-005X], Vallier, Ludovic [0000-0002-3848-2602], and Apollo - University of Cambridge Repository

Subjects
0301 basic medicine, Mesoderm, animal structures, MAP Kinase Signaling System, Ubiquitin-Protein Ligases, education, Human Embryonic Stem Cells, tissue regeneration, Germ layer, Biology, Biochemistry, 03 medical and health sciences, stem cells, Paraxial mesoderm, medicine, Humans, Cell Lineage, Induced pluripotent stem cell, Protein Kinase Inhibitors, Molecular Biology, 030102 biochemistry & molecular biology, Cell Cycle, Embryogenesis, embryo development, Cell Differentiation, RB transcriptional corepressor 1 (RB1), differentiation, Cell Biology, cyclin-dependent kinase (CDK), pluripotency, Cyclin-Dependent Kinases, 3. Good health, Cell biology, Gastrulation, Retinoblastoma Binding Proteins, 030104 developmental biology, medicine.anatomical_structure, embryonic structures, Mesoderm formation, gene expression, Stem cell, signaling
Abstract

The mesoderm is one of the three germ layers produced during gastrulation from which muscle, bones, kidneys, and the cardiovascular system originate. Understanding the mechanisms that control mesoderm specification could inform many applications, including the development of regenerative medicine therapies to manage diseases affecting these tissues. Here, we used human pluripotent stem cells to investigate the role of cell cycle in mesoderm formation. To this end, using small molecules or conditional gene knockdown, we inhibited proteins controlling G1 and G2/M cell cycle phases during the differentiation of human pluripotent stem cells into lateral plate, cardiac, and presomitic mesoderm. These loss-of-function experiments revealed that regulators of the G1 phase, such as cyclin-dependent kinases and pRb (retinoblastoma protein), are necessary for efficient mesoderm formation in a context-dependent manner. Further investigations disclosed that inhibition of the G2/M regulator cyclin-dependent kinase 1 decreases BMP (bone morphogenetic protein) signaling activity specifically during lateral plate mesoderm formation while reducing fibroblast growth factor/extracellular signaling-regulated kinase 1/2 activity in all mesoderm subtypes. Taken together, our findings reveal that cell cycle regulators direct mesoderm formation by controlling the activity of key developmental pathways.

Published
2019

43. CRISPR/Cas9-Mediated Introduction of Specific Heterozygous Mutations in Human Induced Pluripotent Stem Cells.

Author

Brandão KO, Grandela C, Yiangou L, Mummery CL, and Davis RP

Subjects
CRISPR-Cas Systems genetics, Gene Editing methods, Humans, Mutation, RNA, Guide, CRISPR-Cas Systems genetics, RNA, Guide, CRISPR-Cas Systems metabolism, Induced Pluripotent Stem Cells metabolism
Abstract

Advances in genome editing and our ability to derive and differentiate human induced pluripotent stem cells (hiPSCs) into a wide variety of cell types present in the body is revolutionizing how we model human diseases in vitro. Central to this has been the development of the CRISPR/Cas9 system as an inexpensive and highly efficient tool for introducing or correcting disease-associated mutations. However, the ease with which CRISPR/Cas9 enables genetic modification is a double-edged sword, with the challenge now being to introduce changes precisely to just one allele without disrupting the other.In this chapter, we describe strategies to introduce specific mutations into hiPSCs without enrichment steps. Monoallelic modification is contingent on the target activity of the guide RNA, delivery method of the CRISPR/Cas9 components and design of the oligonucleotide(s) transfected. As well as addressing these aspects, we detail high throughput culturing, freezing and screening methods to identify clonal hiPSCs with the desired nucleotide change. This set of protocols offers an efficient and ultimately time- and labor-saving approach for generating isogenic pairs of hiPSCs to detect subtle phenotypic differences caused by the disease variant., (© 2021. Springer Science+Business Media, LLC.)

Published
2022
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44. Reconstruction of the mouse extrahepatic biliary tree using primary human extrahepatic cholangiocyte organoids.

Author

Sampaziotis F, Justin AW, Tysoe OC, Sawiak S, Godfrey EM, Upponi SS, Gieseck RL 3rd, de Brito MC, Berntsen NL, Gómez-Vázquez MJ, Ortmann D, Yiangou L, Ross A, Bargehr J, Bertero A, Zonneveld MCF, Pedersen MT, Pawlowski M, Valestrand L, Madrigal P, Georgakopoulos N, Pirmadjid N, Skeldon GM, Casey J, Shu W, Materek PM, Snijders KE, Brown SE, Rimland CA, Simonic I, Davies SE, Jensen KB, Zilbauer M, Gelson WTH, Alexander GJ, Sinha S, Hannan NRF, Wynn TA, Karlsen TH, Melum E, Markaki AE, Saeb-Parsy K, and Vallier L

Subjects
Animals, Bile Ducts, Extrahepatic cytology, Bile Ducts, Extrahepatic injuries, Biliary Tract cytology, Biliary Tract injuries, Biliary Tract physiology, Cell Transplantation, Cystic Fibrosis Transmembrane Conductance Regulator metabolism, Epithelial Cells drug effects, Epithelial Cells metabolism, Gallbladder injuries, Humans, In Vitro Techniques, Keratin-19 metabolism, Keratin-7 metabolism, Mice, Organoids cytology, Organoids drug effects, Organoids metabolism, Secretin pharmacology, Somatostatin pharmacology, Tissue Scaffolds, gamma-Glutamyltransferase metabolism, Bile Ducts, Extrahepatic physiology, Epithelial Cells cytology, Gallbladder physiology, Organoids physiology, Regeneration physiology, Tissue Engineering methods
Abstract

The treatment of common bile duct (CBD) disorders, such as biliary atresia or ischemic strictures, is restricted by the lack of biliary tissue from healthy donors suitable for surgical reconstruction. Here we report a new method for the isolation and propagation of human cholangiocytes from the extrahepatic biliary tree in the form of extrahepatic cholangiocyte organoids (ECOs) for regenerative medicine applications. The resulting ECOs closely resemble primary cholangiocytes in terms of their transcriptomic profile and functional properties. We explore the regenerative potential of these organoids in vivo and demonstrate that ECOs self-organize into bile duct-like tubes expressing biliary markers following transplantation under the kidney capsule of immunocompromised mice. In addition, when seeded on biodegradable scaffolds, ECOs form tissue-like structures retaining biliary characteristics. The resulting bioengineered tissue can reconstruct the gallbladder wall and repair the biliary epithelium following transplantation into a mouse model of injury. Furthermore, bioengineered artificial ducts can replace the native CBD, with no evidence of cholestasis or occlusion of the lumen. In conclusion, ECOs can successfully reconstruct the biliary tree, providing proof of principle for organ regeneration using human primary cholangiocytes expanded in vitro.

Published
2017
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45. Optimized inducible shRNA and CRISPR/Cas9 platforms for in vitro studies of human development using hPSCs.

Author

Bertero A, Pawlowski M, Ortmann D, Snijders K, Yiangou L, Cardoso de Brito M, Brown S, Bernard WG, Cooper JD, Giacomelli E, Gambardella L, Hannan NR, Iyer D, Sampaziotis F, Serrano F, Zonneveld MC, Sinha S, Kotter M, and Vallier L

Subjects
Cell Differentiation genetics, Cells, Cultured, Embryonic Stem Cells cytology, Gene Knockout Techniques, Humans, Induced Pluripotent Stem Cells cytology, Transcription Factors, CRISPR-Cas Systems genetics, Clustered Regularly Interspaced Short Palindromic Repeats genetics, Cyclin D genetics, Fetal Proteins genetics, Genetic Engineering methods, Nuclear Proteins genetics, Octamer Transcription Factor-3 genetics, T-Box Domain Proteins genetics
Abstract

Inducible loss of gene function experiments are necessary to uncover mechanisms underlying development, physiology and disease. However, current methods are complex, lack robustness and do not work in multiple cell types. Here we address these limitations by developing single-step optimized inducible gene knockdown or knockout (sOPTiKD or sOPTiKO) platforms. These are based on genetic engineering of human genomic safe harbors combined with an improved tetracycline-inducible system and CRISPR/Cas9 technology. We exemplify the efficacy of these methods in human pluripotent stem cells (hPSCs), and show that generation of sOPTiKD/KO hPSCs is simple, rapid and allows tightly controlled individual or multiplexed gene knockdown or knockout in hPSCs and in a wide variety of differentiated cells. Finally, we illustrate the general applicability of this approach by investigating the function of transcription factors (OCT4 and T), cell cycle regulators (cyclin D family members) and epigenetic modifiers (DPY30). Overall, sOPTiKD and sOPTiKO provide a unique opportunity for functional analyses in multiple cell types relevant for the study of human development., Competing Interests: The authors declare no competing or financial interests., (© 2016. Published by The Company of Biologists Ltd.)

Published
2016
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