Your search keyword '"embryonic stem cells"' showing total 2,312 results

1. Correction: Utx Is Required for Proper Induction of Ectoderm and Mesoderm during Differentiation of Embryonic Stem Cells.

Author

Torres, Cristina Morales, Laugesen, Anne, and Helin, Kristian

Subjects

*MESODERM, *EMBRYONIC stem cells, *ECTODERM, *GENE expression, *GENETIC regulation

Abstract

This document is a correction notice for an article titled "Utx Is Required for Proper Induction of Ectoderm and Mesoderm during Differentiation of Embryonic Stem Cells." The authors address concerns about images in Figures 1, 5, 7, and S2 and provide additional information, corrected figures, and underlying data for these experiments. The authors apologize for the errors in the published article. The document also includes graphs and supporting information related to the study. [Extracted from the article]

Published

2024

2. Malic enzyme 1 knockout has no deleterious phenotype and is favored in the male germline under standard laboratory conditions.

Author

Alektiar, Jonathan M., Shan, Mengrou, Radyk, Megan D., Zhang, Li, Halbrook, Christopher J., Lin, Lin, Espinoza, Carlos, Mier, Ivan F., Lavoie, Brooke L., Salvatore, Lucie, Pasca di Magliano, Marina, Cantley, Lewis C., Mueller, Jacob L., and Lyssiotis, Costas A.

Subjects

*PHENOTYPES, *IMMUNOGLOBULIN class switching, *EMBRYONIC stem cells, *BLOOD cell count, *GERM cells

Abstract

Malic Enzyme 1 (ME1) plays an integral role in fatty acid synthesis and cellular energetics through its production of NADPH and pyruvate. As such, it has been identified as a gene of interest in obesity, type 2 diabetes, and an array of epithelial cancers, with most work being performed in vitro. The current standard model for ME1 loss in vivo is the spontaneous Mod-1 null allele, which produces a canonically inactive form of ME1. Herein, we describe two new genetically engineered mouse models exhibiting ME1 loss at dynamic timepoints. Using murine embryonic stem cells and Flp/FRT and Cre/loxP class switch recombination, we established a germline Me1 knockout model (Me1 KO) and an inducible conditional knockout model (Me1 cKO), activated upon tamoxifen treatment in adulthood. Collectively, neither the Me1 KO nor Me1 cKO models exhibited deleterious phenotype under standard laboratory conditions. Knockout of ME1 was validated by immunohistochemistry and genotype confirmed by PCR. Transmission patterns favor Me1 loss in Me1 KO mice when maternally transmitted to male progeny. Hematological examination of these models through complete blood count and serum chemistry panels revealed no discrepancy with their wild-type counterparts. Orthotopic pancreatic tumors in Me1 cKO mice grow similarly to Me1 expressing mice. Similarly, no behavioral phenotype was observed in Me1 cKO mice when aged for 52 weeks. Histological analysis of several tissues revealed no pathological phenotype. These models provide a more modern approach to ME1 knockout in vivo while opening the door for further study into the role of ME1 loss under more biologically relevant, stressful conditions. [ABSTRACT FROM AUTHOR]

Published

2024

3. SUMO-dependent transcriptional repression by Sox2 inhibits the proliferation of neural stem cells.

Author

Marelli, Elisa, Hughes, Jaime, and Scotting, Paul J.

Subjects

*EMBRYONIC stem cells, *CELL proliferation, *CELL cycle, *NEURAL stem cells

Abstract

Sox2 is known for its roles in maintaining the stem cell state of embryonic stem cells and neural stem cells. In particular, it has been shown to slow the proliferation of these cell types. It is also known for its effects as an activating transcription factor. Despite this, analysis of published studies shows that it represses as many genes as it activates. Here, we identify a new set of target genes that Sox2 represses in neural stem cells. These genes are associated with centrosomes, centromeres and other aspects of cell cycle control. In addition, we show that SUMOylation of Sox2 is necessary for the repression of these genes and for its repressive effects on cell proliferation. Together, these data suggest that SUMO-dependent repression of this group of target genes is responsible for the role of Sox2 in regulating the proliferation of neural stem cells. [ABSTRACT FROM AUTHOR]

Published

2024

4. The shapes of elongating gastruloids are consistent with convergent extension driven by a combination of active cell crawling and differential adhesion.

Author

de Jong, Martijn A., Adegeest, Esmée, Bérenger-Currias, Noémie M. L. P., Mircea, Maria, Merks, Roeland M. H., and Semrau, Stefan

Subjects

*GASTRULATION, *EMBRYOLOGY, *EMBRYONIC stem cells, *POTTS model, *MAMMALIAN embryos

Abstract

Gastruloids have emerged as highly useful in vitro models of mammalian gastrulation. One of the most striking features of 3D gastruloids is their elongation, which mimics the extension of the embryonic anterior-posterior axis. Although axis extension is crucial for development, the underlying mechanism has not been fully elucidated in mammalian species. Gastruloids provide an opportunity to study this morphogenic process in vitro. Here, we measure and quantify the shapes of elongating gastruloids and show, by Cellular Potts model simulations based on a novel, optimized algorithm, that convergent extension, driven by a combination of active cell crawling and differential adhesion can explain the observed shapes. We reveal that differential adhesion alone is insufficient and also directly observe hallmarks of convergent extension by time-lapse imaging of gastruloids. Finally, we show that gastruloid elongation can be abrogated by inhibition of the Rho kinase pathway, which is involved in convergent extension in vivo. All in all, our study demonstrates, how gastruloids can be used to elucidate morphogenic processes in embryonic development. Author summary: During embryonic development, a mammalian embryo develops from a single cell to a complete organism with a complex body plan. To ensure that tissues and organs are formed exactly in the right places, the embryo goes through a highly orchestrated series of events that establish the fundamental axes of the body, such as the anterior-posterior axis, which runs from the head (anterior) to the tail (posterior). Extensive elongation along this axis is crucial for proper development, but the underlying mechanisms are not completely understood, partially because experimentation with embryos is cumbersome. In this study, we used aggregates of mouse embryonic stem cells, known as gastruloids, which mimic elements of embryonic development, most importantly elongation, in a dish. We developed a computational approach to simulate aggregate shapes and used measured aggregate shapes to decide between multiple hypotheses for the mechanisms driving elongation. We found that the combination of two separate mechanisms can explain the measured shapes: 1. active crawling of cells that leads to a narrowing in one direction and extension in the perpendicular direction (like when squeezing a stress ball) and 2. differences in the stickiness (adhesion) between different types of cells. [ABSTRACT FROM AUTHOR]

Published

2024

5. 4D nucleome equation predicts gene expression controlled by long-range enhancer-promoter interaction.

Author

Wang, Zihao, Luo, Songhao, Zhang, Zhenquan, Zhou, Tianshou, and Zhang, Jiajun

Subjects

*GENE expression, *EMBRYONIC stem cells, *GENE expression profiling, *INFERENTIAL statistics, *EQUATIONS

Abstract

Recent experimental evidence strongly supports that three-dimensional (3D) long-range enhancer-promoter (E-P) interactions have important influences on gene-expression dynamics, but it is unclear how the interaction information is translated into gene expression over time (4D). To address this question, we developed a general theoretical framework (named as a 4D nucleome equation), which integrates E-P interactions on chromatin and biochemical reactions of gene transcription. With this equation, we first present the distribution of mRNA counts as a function of the E-P genomic distance and then reveal a power-law scaling of the expression level in this distance. Interestingly, we find that long-range E-P interactions can induce bimodal and trimodal mRNA distributions. The 4D nucleome equation also allows for model selection and parameter inference. When this equation is applied to the mouse embryonic stem cell smRNA-FISH data and the E-P genomic-distance data, the predicted E-P contact probability and mRNA distribution are in good agreement with experimental results. Further statistical inference indicates that the E-P interactions prefer to modulate the mRNA level by controlling promoter activation and transcription initiation rates. Our model and results provide quantitative insight into both spatiotemporal gene-expression determinants (i.e., long-range E-P interactions) and cellular fates during development. Author summary: Gene expression is an essential biological process in all organisms. Numerous experimental studies have reported that the long-range enhancer-promoter (E-P) interaction on three-dimensional (3D) chromatin architecture plays important roles in regulating gene expression and cell functions, but the quantitative and qualitative impact of E-P interaction on gene expression over time is unclear. We develop a theoretically and numerically efficient model (called the 4D nucleome equation) to couple E-P interaction with gene expression and use this equation to characterize dynamic behavior. Then, we obtain the theoretical distribution of mRNAs and predict the gene expression profiles under E-P regulations. Interestingly, we find that E-P interactions can induce bimodal and trimodal shapes of mRNA distribution. When applying this framework to mouse embryonic stem cell data to investigate the dynamical behaviors of E-P interaction and gene expression, we reproduce the experimentally measured E-P contact frequencies and mRNA distribution under different E-P interactions. Our results support the picture of an essential mechanism for explaining phenotypic diversity and cellular decision-making. [ABSTRACT FROM AUTHOR]

Published

2023

6. Transcription induces context-dependent remodeling of chromatin architecture during differentiation.

Author

Chahar, Sanjay, Ben Zouari, Yousra, Salari, Hossein, Kobi, Dominique, Maroquenne, Manon, Erb, Cathie, Molitor, Anne M., Mossler, Audrey, Karasu, Nezih, Jost, Daniel, and Sexton, Tom

Subjects

*CHROMATIN, *EMBRYONIC stem cells, *RNA polymerases, *CHROMOSOMES, *GENETIC transcription regulation

Abstract

Metazoan chromosomes are organized into discrete spatial domains (TADs), believed to contribute to the regulation of transcriptional programs. Despite extensive correlation between domain organization and gene activity, a direct mechanistic link is unclear, with perturbation studies often showing little effect. To follow chromatin architecture changes during development, we used Capture Hi-C to interrogate the domains around key differentially expressed genes during mouse thymocyte maturation, uncovering specific remodeling events. Notably, one TAD boundary was broadened to accommodate RNA polymerase elongation past the border, and subdomains were formed around some activated genes without changes in CTCF binding. The ectopic induction of some genes was sufficient to recapitulate domain formation in embryonic stem cells, providing strong evidence that transcription can directly remodel chromatin structure. These results suggest that transcriptional processes drive complex chromosome folding patterns that can be important in certain genomic contexts. Links between genome organization and transcriptional control have been controversial and unclear. Although most TADs (topologically associated domains) are stable through development, this study shows by ectopic induction in ESCs that transcription can directly remodel TADs, with a context-dependent sensitivity. [ABSTRACT FROM AUTHOR]

Published

2023

7. Significant decrease of maternal mitochondria carryover using optimized spindle-chromosomal complex transfer.

Author

Liao, Xiaoyu, Li, Wenzhi, Lin, Kaibo, Jin, Wei, Zhang, Shaozhen, Wang, Yao, Ma, Meng, Xie, Yating, Yu, Weina, Yan, Zhiguang, Gao, Hongyuan, Zhao, Leiwen, Si, Jiqiang, Wang, Yun, Lin, Jiaying, Chen, Chen, Chen, Li, Kuang, Yanping, and Lyu, Qifeng

Subjects

*MITOCHONDRIAL DNA, *INTRACYTOPLASMIC sperm injection, *GENETIC drift, *MITOCHONDRIA, *EMBRYONIC stem cells, *EMBRYO transfer, *HUMAN embryology

Abstract

Mutations in mitochondrial DNA (mtDNA) contribute to a variety of serious multi-organ human diseases, which are strictly inherited from the maternal germline. However, there is currently no curative treatment. Attention has been focused on preventing the transmission of mitochondrial diseases through mitochondrial replacement (MR) therapy, but levels of mutant mtDNA can often unexpectedly undergo significant changes known as mitochondrial genetic drift. Here, we proposed a novel strategy to perform spindle-chromosomal complex transfer (SCCT) with maximal residue removal (MRR) in metaphase II (MII) oocytes, thus hopefully eliminated the transmission of mtDNA diseases. With the MRR procedure, we initially investigated the proportions of mtDNA copy numbers in isolated karyoplasts to those of individual oocytes. Spindle-chromosomal morphology and copy number variation (CNV) analysis also confirmed the safety of this method. Then, we reconstructed oocytes by MRR-SCCT, which well developed to blastocysts with minimal mtDNA residue and normal chromosomal copy numbers. Meanwhile, we optimized the manipulation order between intracytoplasmic sperm injection (ICSI) and SCC transfer and concluded that ICSI-then-transfer was conducive to avoid premature activation of reconstructed oocytes in favor of normal fertilization. Offspring of mice generated by embryos transplantation in vivo and embryonic stem cells derivation further presented evidences for competitive development competence and stable mtDNA carryover without genetic drift. Importantly, we also successfully accomplished SCCT in human MII oocytes resulting in tiny mtDNA residue and excellent embryo development through MRR manipulation. Taken together, our preclinical mouse and human models of the MRR-SCCT strategy not only demonstrated efficient residue removal but also high compatibility with normal embryo development, thus could potentially be served as a feasible clinical treatment to prevent the transmission of inherited mtDNA diseases. Mutations in mitochondrial DNA (mtDNA) cause a variety of serious multi-organ human diseases, but existing means of preventing mtDNA transmission are problematic. This study presents a novel technically optimized strategy to perform spindle-chromosomal complex transfer (SCCT) with minimal mtDNA carryover and excellent embryo development in both mouse and human models. [ABSTRACT FROM AUTHOR]

Published

2023

8. Saturation genome editing of 11 codons and exon 13 of BRCA2 coupled with chemotherapeutic drug response accurately determines pathogenicity of variants.

Author

Sahu, Sounak, Sullivan, Teresa L., Mitrophanov, Alexander Y., Galloux, Mélissa, Nousome, Darryl, Southon, Eileen, Caylor, Dylan, Mishra, Arun Prakash, Evans, Christine N., Clapp, Michelle E., Burkett, Sandra, Malys, Tyler, Chari, Raj, Biswas, Kajal, and Sharan, Shyam K.

Subjects

*BRCA genes, *GENOME editing, *BACTERIAL artificial chromosomes, *GENETIC variation, *EMBRYONIC stem cells, *GENETIC code

Abstract

The unknown pathogenicity of a significant number of variants found in cancer-related genes is attributed to limited epidemiological data, resulting in their classification as variant of uncertain significance (VUS). To date, Breast Cancer gene-2 (BRCA2) has the highest number of VUSs, which has necessitated the development of several robust functional assays to determine their functional significance. Here we report the use of a humanized-mouse embryonic stem cell (mESC) line expressing a single copy of the human BRCA2 for a CRISPR-Cas9-based high-throughput functional assay. As a proof-of-principle, we have saturated 11 codons encoded by BRCA2 exons 3, 18, 19 and all possible single-nucleotide variants in exon 13 and multiplexed these variants for their functional categorization. Specifically, we used a pool of 180-mer single-stranded donor DNA to generate all possible combination of variants. Using a high throughput sequencing-based approach, we show a significant drop in the frequency of non-functional variants, whereas functional variants are enriched in the pool of the cells. We further demonstrate the response of these variants to the DNA-damaging agents, cisplatin and olaparib, allowing us to use cellular survival and drug response as parameters for variant classification. Using this approach, we have categorized 599 BRCA2 variants including 93-single nucleotide variants (SNVs) across the 11 codons, of which 28 are reported in ClinVar. We also functionally categorized 252 SNVs from exon 13 into 188 functional and 60 non-functional variants, demonstrating that saturation genome editing (SGE) coupled with drug sensitivity assays can enhance functional annotation of BRCA2 VUS. Author summary: The exponential rise in genetic sequencing led to the identification of several missense variants. However, its clinical utility is often limited by our ability to determine the functional impact of genetic variants. This has resulted in the identification of many variant of uncertain significance (VUS), particularly in BRCA2. Several functional assays have been developed to ascertain the impact of VUSs on protein function that can be used to determine their pathogenicity. Our mouse ES cell (mESC)-based method includes generation of individual BRCA2 variants in a bacterial artificial chromosome (BAC) by recombineering and assess their expression in mouse ES cells. These cells can then be used to determine how the variants affect mESC viability and sensitivity to DNA damaging agents. Although the assay has high sensitivity and specificity, the process is time consuming and labor-intensive. To overcome these limitations, here we report the development of a CRISPR-Cas9 based high-throughput approach that can be used to classify multiple BRCA2 variants. Specifically, we utilized the BRCA2-independent single-stranded annealing pathway to efficiently knock-in targeted mutations in mESCs using a library of single-stranded DNA donors. Not only do our results support the ClinVar classification of some variants, but we also assign clinical significance to several VUSs, for which no functional data is currently available. [ABSTRACT FROM AUTHOR]

Published

2023

9. Micelle-like clusters in phase-separated Nanog condensates: A molecular simulation study.

Author

Mizutani, Azuki, Tan, Cheng, Sugita, Yuji, and Takada, Shoji

Subjects

*EMBRYONIC stem cells, *RNA polymerases, *HYDROPHOBIC interactions, *GENETIC transcription regulation, *TRANSCRIPTION factors

Abstract

The phase separation model for transcription suggests that transcription factors (TFs), coactivators, and RNA polymerases form biomolecular condensates around active gene loci and regulate transcription. However, the structural details of condensates remain elusive. In this study, for Nanog, a master TF in mammalian embryonic stem cells known to form protein condensates in vitro, we examined protein structures in the condensates using residue-level coarse-grained molecular simulations. Human Nanog formed micelle-like clusters in the condensate. In the micelle-like cluster, the C-terminal disordered domains, including the tryptophan repeat (WR) regions, interacted with each other near the cluster center primarily via hydrophobic interaction. In contrast, hydrophilic disordered N-terminal and DNA-binding domains were exposed on the surface of the clusters. Electrostatic attractions of these surface residues were responsible for bridging multiple micelle-like structures in the condensate. The micelle-like structure and condensate were dynamic and liquid-like. Mutation of tryptophan residues in the WR region which was implicated to be important for a Nanog function resulted in dissolution of the Nanog condensate. Finally, to examine the impact of Nanog cluster to DNA, we added DNA fragments to the Nanog condensate. Nanog DNA-binding domains exposed to the surface of the micelle-like cluster could recruit more than one DNA fragments, making DNA-DNA distance shorter. Author summary: In eukaryotic transcription regulation, enhancer elements far from the promoter are known to modulate transcriptional activity, but the molecular mechanism remains elusive. One of these models, the phase separation model, suggests that transcription factors (TFs), coactivators, and transcription machinery form biomolecular condensates that include enhancer and promoter elements, making enhancer-promoter communication possible via the protein network in the condensate. Nanog, one of the core TFs involved in mammalian embryonic stem cells, has been reported to have the ability to form condensates. In this study, we addressed the structural details of Nanog condensates by performing residue-level coarse-grained molecular simulations. We found that Nanog formed micelle-like clusters via primarily hydrophobic interactions between tryptophan repeat regions in the C-terminal disordered domains within the condensate. On the other hand, highly charged N-terminal and DNA-binding domains were exposed to the surface of the micelle and were responsible for bridging many micelles into a condensate. The micelle-like clusters and condensate were dynamic and liquid-like. In addition, Nanog condensates could induce DNA-DNA attraction mediated by micelle-like structures. [ABSTRACT FROM AUTHOR]

Published

2023

10. Optimization of piggyBac transposon-mediated gene transfer method in common marmoset embryos.

Author

Kohri, Nanami, Ota, Mitsuo, Kousaku, Hikaru, Minakawa, Eiko N., Seki, Kazuhiko, and Tomioka, Ikuo

Subjects

*CALLITHRIX jacchus, *GENETIC transformation, *TRANSPOSONS, *EMBRYOS, *EMBRYONIC stem cells, *ALZHEIMER'S disease, *MARMOSETS

Abstract

Generating non-human primate models of human diseases is important for the development of therapeutic strategies especially for neurodegenerative diseases. The common marmoset has attracted attention as a new experimental animal model, and many transgenic marmosets have been produced using lentiviral vector-mediated transgenesis. However, lentiviral vectors have a size limitation of up to 8 kb in length for transgene applications. Therefore, the present study aimed to optimize a piggyBac transposon-mediated gene transfer method in which transgenes longer than 8 kb were injected into the perivitelline space of marmoset embryos, followed by electroporation. We constructed a long piggyBac vector carrying the gene responsible for Alzheimer's disease. The optimal weight ratio of the piggyBac transgene vector to the piggyBac transposase mRNA was examined using mouse embryos. Transgene integration into the genome was confirmed in 70.7% of embryonic stem cells established from embryos injected with 1000 ng of transgene and transposase mRNA. Under these conditions, long transgenes were introduced into marmoset embryos. All embryos survived after transgene introduction treatment, and transgenes were detected in 70% of marmoset embryos. The transposon-mediated gene transfer method developed in this study can be applied to the genetic modification of non-human primates, as well as large animals. [ABSTRACT FROM AUTHOR]

Published

2023

11. Integration of a multi-omics stem cell differentiation dataset using a dynamical model.

Author

van den Berg, Patrick R., Bérenger-Currias, Noémie M. L. P., Budnik, Bogdan, Slavov, Nikolai, and Semrau, Stefan

Subjects

*STEM cells, *EMBRYONIC stem cells, *MULTIOMICS, *CYTOLOGY, *PLURIPOTENT stem cells

Abstract

Stem cell differentiation is a highly dynamic process involving pervasive changes in gene expression. The large majority of existing studies has characterized differentiation at the level of individual molecular profiles, such as the transcriptome or the proteome. To obtain a more comprehensive view, we measured protein, mRNA and microRNA abundance during retinoic acid-driven differentiation of mouse embryonic stem cells. We found that mRNA and protein abundance are typically only weakly correlated across time. To understand this finding, we developed a hierarchical dynamical model that allowed us to integrate all data sets. This model was able to explain mRNA-protein discordance for most genes and identified instances of potential microRNA-mediated regulation. Overexpression or depletion of microRNAs identified by the model, followed by RNA sequencing and protein quantification, were used to follow up on the predictions of the model. Overall, our study shows how multi-omics integration by a dynamical model could be used to nominate candidate regulators. Author summary: Pluripotent stem cells, which can be derived from an adult individual, can be grown indefinitely in a dish and turned into each cell type of the body. These abilities enable applications of stem cells in basic research and regenerative medicine. Differentiation, the conversion into a precisely defined cell type, typically requires complex protocols that often have low efficiency. A better understanding of the molecular mechanisms underlying differentiation could help us improve existing protocols. Here, we studied the differentiation of embryonic stem cells induced by a small molecule (retinoic acid). We measured the abundances of three important classes of biomolecules–micro RNAs, messenger RNAs and proteins–at multiple time points during a 96 h-long differentiation experiment. We observed changes in the abundances of thousands of molecules. To make sense of these measurements we developed a mathematical model that connects the different classes of biomolecules and aims to predict their dynamics. Such models might help us identify new opportuntities to control differentiation at the molecular level. The data set we created, which we provide through an easily accessible web application, will also be a useful resource for other researchers interested in stem cell biology. [ABSTRACT FROM AUTHOR]

Published

2023

12. One model fits all: Combining inference and simulation of gene regulatory networks.

Author

Ventre, Elias, Herbach, Ulysse, Espinasse, Thibault, Benoit, Gérard, and Gandrillon, Olivier

Subjects

*GENE regulatory networks, *EMBRYONIC stem cells, *GENE expression

Abstract

The rise of single-cell data highlights the need for a nondeterministic view of gene expression, while offering new opportunities regarding gene regulatory network inference. We recently introduced two strategies that specifically exploit time-course data, where single-cell profiling is performed after a stimulus: HARISSA, a mechanistic network model with a highly efficient simulation procedure, and CARDAMOM, a scalable inference method seen as model calibration. Here, we combine the two approaches and show that the same model driven by transcriptional bursting can be used simultaneously as an inference tool, to reconstruct biologically relevant networks, and as a simulation tool, to generate realistic transcriptional profiles emerging from gene interactions. We verify that CARDAMOM quantitatively reconstructs causal links when the data is simulated from HARISSA, and demonstrate its performance on experimental data collected on in vitro differentiating mouse embryonic stem cells. Overall, this integrated strategy largely overcomes the limitations of disconnected inference and simulation. Author summary: Gene regulatory network (GRN) inference is an old problem, to which single-cell data has recently offered new challenges and breakthrough potential. Many GRN inference methods based on single-cell transcriptomic data have been developed over the last few years, while GRN simulation tools have also been proposed for generating synthetic datasets with realistic features. However, except for benchmarking purposes, these two fields remain largely disconnected. In this work, building on a combination of two methods we recently described, we show that a particular GRN model can be used simultaneously as an inference tool, to reconstruct a biologically relevant network from time-course single-cell gene expression data, and as a simulation tool, to generate realistic transcriptional profiles in a non-trivial way through gene interactions. This integrated strategy demonstrates the benefits of using the same executable model for both simulation and inference. [ABSTRACT FROM AUTHOR]

Published

2023

13. Different congenital hydrocephalus–associated mutations in Trim71 impair stem cell differentiation via distinct gain-of-function mechanisms.

Author

Liu, Qiuying, Novak, Mariah K., Pepin, Rachel M., Maschhoff, Katharine R., and Hu, Wenqian

Subjects

*CELL differentiation, *STEM cells, *EMBRYONIC stem cells, *NEURONAL differentiation, *RNA-binding proteins

Abstract

Congenital hydrocephalus (CH) is a common neurological disorder affecting many newborns. Imbalanced neurogenesis is a major cause of CH. Multiple CH-associated mutations are within the RNA-binding domain of Trim71, a conserved, stem cell–specific RNA-binding protein. How these mutations alter stem cell fate is unclear. Here, we show that the CH-associated mutations R595H and R783H in Trim71 accelerate differentiation and enhance neural lineage commitment in mouse embryonic stem cells (mESCs), and reduce binding to mRNAs targeted by wild-type Trim71, consistent with previous reports. Unexpectedly, however, each mutant binds an ectopic and distinct repertoire of target mRNAs. R595H-Trim71, but not R783H-Trim71 nor wild-type Trim71, binds the mRNA encoding β-catenin and represses its translation. Increasing β-catenin by overexpression or treatment with a Wnt agonist specifically restores differentiation of R595H-Trim71 mESCs. These results suggest that Trim71 mutations give rise to unique gain-of-function pathological mechanisms in CH. Further, our studies suggest that disruption of the Wnt/β-catenin signaling pathway can be used to stratify disease etiology and develop precision medicine approaches for CH. This study shows that two congenital hydrocephalus (CH)-associated mutations in Trim71 accelerate mouse embryonic stem cells differentiation into neurons; while these mutations reduce binding to known Trim71 target mRNAs, the mutant Trim71s bind new and distinct targets, leading to gain-of-function effects that may contribute to the etiology of CH. [ABSTRACT FROM AUTHOR]

Published

2023

14. Denuded Descemet's membrane supports human embryonic stem cell-derived retinal pigment epithelial cell culture.

Author

Daniele, Elena, Bosio, Lorenzo, Hussain, Noor Ahmed, Ferrari, Barbara, Ferrari, Stefano, Barbaro, Vanessa, McArdle, Brian, Rassu, Nicolò, Mura, Marco, Parmeggiani, Francesco, and Ponzin, Diego

Subjects

*EPITHELIAL cell culture, *RHODOPSIN, *CHROMATOPHORES, *TIGHT junctions, *CELL morphology, *EMBRYONIC stem cells, *CELL culture

Abstract

Recent clinical studies suggest that retinal pigment epithelial (RPE) cell replacement therapy may preserve vision in retinal degenerative diseases. Scaffold-based methods are being tested in ongoing clinical trials for delivering pluripotent-derived RPE cells to the back of the eye. The aim of this study was to investigate human embryonic stem cell-derived retinal pigment epithelial (hESC-RPE) cells survival and behaviour on a decellularized Descemet's Membrane (DM), which may be of clinical relevance in retinal transplantation. DMs were isolated from human donor corneas and treated with thermolysin. The DM surface topology and the efficiency of the denudation method were evaluated by atomic force microscope, scanning electron microscopy and histology. hESC-RPE cells were seeded onto the endothelial-side surface of decellularized DM in order to determine the potential of the membrane to support hESC-RPE cell culture, alongside maintaining their viability. Integrity of the hESC-RPE monolayer was assessed by measuring transepithelial resistance. RPE-specific gene expression and growth factors secretion were assessed to confirm maturation and functionality of the cells over the new substrate. Thermolysin treatment did not affect the integrity of the tissue, thus ensuring a reliable method to standardize the preparation of decellularized DM. 24 hours post-seeding, hESC-RPE cell attachment and initial proliferation rate over the denuded DM were higher than hESC-RPE cells cultured on tissue culture inserts. On the new matrix, hESC-RPE cells succeeded in forming an intact monolayer with mature tight junctions. The resulting cell culture showed characteristic RPE cell morphology and proper protein localization. Gene expression analysis and VEGF secretion demonstrate DM provides supportive scaffolding and inductive properties to enhance hESC-RPE cells maturation. Decellularized DM was shown to be capable of sustaining hESC-RPE cells culture, thus confirming to be potentially a suitable candidate for retinal cell therapy. [ABSTRACT FROM AUTHOR]

Published

2023

15. Analysis of regulatory sequences in exosomal DNA of NANOGP8.

Author

Vaidya, Manjusha, Smith, Jonhoi, Field, Melvin, and Sugaya, Kiminobu

Subjects

*STEM cell factor, *CANCER stem cells, *NEURAL stem cells, *EMBRYONIC stem cells, *SEQUENCE analysis, *TRANSCRIPTION factors, *SOX2 protein

Abstract

Exosomes participate in intercellular communication by transporting functionally active molecules. Such cargo from the original cells comprising proteins, micro-RNA, mRNA, single-stranded (ssDNA) and double-stranded DNA (dsDNA) molecules pleiotropically transforms the target cells. Although cancer cells secrete exosomes carrying a significant level of DNA capable of modulating oncogene expression in a recipient cell, the regulatory mechanism is unknown. We have previously reported that cancer cells produce exosomes containing NANOGP8 DNA. NANOGP8 is an oncogenic paralog of embryonic stem cell transcription factor NANOG and does not express in cells since it is a pseudogene. However, in this study, we evaluated NANOGP8 expression in glioblastoma multiforme (GBM) tissue from a surgically removed brain tumor of a patient. Significantly higher NANOGP8 transcription was observed in GBM cancer stem cells (CSCs) than in GBM cancer cells or neural stem cells (NSCs), despite identical sequences of NANOGP8-upstream genomic region in all the cell lines. This finding suggests that upstream genomic sequences of NANOGP8 may have environment-dependent promoter activity. We also found that the regulatory sequences upstream of exosomal NANOGP8 GBM DNA contain multiple core promoter elements, transcription factor binding sites, and segments of human viruses known for their oncogenic role. The exosomal sequence of NANOGP8-upstream GBM DNA is different from corresponding genomic sequences in CSCs, cancer cells, and NSCs as well as from the sequences reported by NCBI. These sequence dissimilarities suggest that exosomal NANOGP8 GBM DNA may not be a part of the genomic DNA. Exosomes possibly acquire this DNA from other sources where it is synthesized by an unknown mechanism. The significance of exosome-bestowed regulatory elements in the transcription of promoter-less retrogene such as NANOGP8 remains to be determined. [ABSTRACT FROM AUTHOR]

Published

2023

16. Direct implantation of hair-follicle-associated pluripotent (HAP) stem cells repairs intracerebral hemorrhage and reduces neuroinflammation in mouse model.

Author

Obara, Koya, Shirai, Kyoumi, Hamada, Yuko, Arakawa, Nobuko, Hasegawa, Ayami, Takaoka, Nanako, Aki, Ryoichi, Hoffman, Robert M., and Amoh, Yasuyuki

Subjects

*STEM cells, *CEREBRAL hemorrhage, *NEURAL stem cells, *EMBRYONIC stem cells, *ASTROCYTES, *INDUCED pluripotent stem cells, *LABORATORY mice, *PLURIPOTENT stem cells

Abstract

Intracerebral hemorrhage (ICH) is a leading cause of mortality with ineffective treatment. Hair-follicle-associated pluripotent (HAP) stem cells can differentiate into neurons, glial cells and many other types of cells. HAP stem cells have been shown to repair peripheral-nerve and spinal-cord injury in mouse models. In the present study, HAP stem cells from C57BL/6J mice were implanted into the injured brain of C57BL/6J or nude mice with induced ICH. After allo transplantation, HAP stem cells differentiated to neurons, astrocytes, oligodendrocytes, and microglia in the ICH site of nude mice. After autologous transplantation in C57BL/6J mice, HAP stem cells suppressed astrocyte and microglia infiltration in the injured brain. The mRNA expression levels of IL-10 and TGF-β1, measured by quantitative Real-Time RT-PCR, in the brain of C57BL/6J mice with ICH was increased by HAP-stem-cell implantation compared to the non-implanted mice. Quantitative sensorimotor function analysis, with modified limb-placing test and the cylinder test, demonstrated a significant functional improvement in the HAP-stem-cell-implanted C57BL/6J mice, compared to non-implanted mice. HAP stem cells have critical advantages over induced pluripotent stem cells, embryonic stem cells as they do not develop tumors, are autologous, and do not require genetic manipulation. The present study demonstrates future clinical potential of HAP-stem-cell repair of ICH, currently a recalcitrant disease. [ABSTRACT FROM AUTHOR]

Published

2023

17. ERK1/2 signalling dynamics promote neural differentiation by regulating chromatin accessibility and the polycomb repressive complex.

Author

Semprich, Claudia I., Davidson, Lindsay, Amorim Torres, Adriana, Patel, Harshil, Briscoe, James, Metzis, Vicki, and Storey, Kate G.

Subjects

*HUMAN embryonic stem cells, *CHROMATIN, *FIBROBLAST growth factors, *NERVE tissue proteins, *HUMAN embryos, *EMBRYONIC stem cells, *NEURAL stem cells

Abstract

Fibroblast growth factor (FGF) is a neural inducer in many vertebrate embryos, but how it regulates chromatin organization to coordinate the activation of neural genes is unclear. Moreover, for differentiation to progress, FGF signalling must decline. Why these signalling dynamics are required has not been determined. Here, we show that dephosphorylation of the FGF effector kinase ERK1/2 rapidly increases chromatin accessibility at neural genes in mouse embryos, and, using ATAC-seq in human embryonic stem cell derived spinal cord precursors, we demonstrate that this occurs genome-wide across neural genes. Importantly, ERK1/2 inhibition induces precocious neural gene transcription, and this involves dissociation of the polycomb repressive complex from key gene loci. This takes place independently of subsequent loss of the repressive histone mark H3K27me3 and transcriptional onset. Transient ERK1/2 inhibition is sufficient for the dissociation of the repressive complex, and this is not reversed on resumption of ERK1/2 signalling. Moreover, genomic footprinting of sites identified by ATAC-seq together with ChIP-seq for polycomb protein Ring1B revealed that ERK1/2 inhibition promotes the occupancy of neural transcription factors (TFs) at non-polycomb as well as polycomb associated sites. Together, these findings indicate that ERK1/2 signalling decline promotes global changes in chromatin accessibility and TF binding at neural genes by directing polycomb and other regulators and appears to serve as a gating mechanism that provides directionality to the process of differentiation. FGF is a neural inducer in many vertebrate embryos, but does it regulates chromatin organization to coordinate the activation of neural genes? This study reveals how a decline in FGF effector kinase ERK1/2 signaling promotes neural differentiation by regulating chromatin accessibility and polycomb protein occupancy at neural genes in the mouse embryo and in human pluripotent cell-derived neural precursors. [ABSTRACT FROM AUTHOR]

Published

2022

18. Long-range axonal projections of transplanted mouse embryonic stem cell-derived hypothalamic neurons into adult mouse brain.

Author

Kawata, Miho, Kodani, Yu, Ohkuma, Mahito, Miyachi, Ei-ichi, Kaneko, Yoko S., Nakashima, Akira, Suga, Hidetaka, Kameyama, Toshiki, Saito, Kanako, and Nagasaki, Hiroshi

Subjects

*HYPOTHALAMUS, *NEURONS, *NEURAL circuitry, *SUBSTANTIA nigra, *CELL populations, *PARAVENTRICULAR nucleus, *EMBRYONIC stem cells

Abstract

The hypothalamus is comprised of heterogenous cell populations and includes highly complex neural circuits that regulate the autonomic nerve system. Its dysfunction therefore results in severe endocrine disorders. Although recent experiments have been conducted for in vitro organogenesis of hypothalamic neurons from embryonic stem (ES) or induced pluripotent stem (iPS) cells, whether these stem cell-derived hypothalamic neurons can be useful for regenerative medicine remains unclear. We therefore performed orthotopic transplantation of mouse ES cell (mESC)-derived hypothalamic neurons into adult mouse brains. We generated electrophysiologically functional hypothalamic neurons from mESCs and transplanted them into the supraoptic nucleus of mice. Grafts extended their axons along hypothalamic nerve bundles in host brain, and some of them even projected into the posterior pituitary (PPit), which consists of distal axons of the magnocellular neurons located in hypothalamic supraoptic and paraventricular nuclei. The axonal projections to the PPit were not observed when the mESC-derived hypothalamic neurons were ectopically transplanted into the substantia nigra reticular part. These findings suggest that our stem cell-based orthotopic transplantation approach might contribute to the establishment of regenerative medicine for hypothalamic and pituitary disorders. [ABSTRACT FROM AUTHOR]

Published

2022

19. Dual specificity phosphatase 7 drives the formation of cardiac mesoderm in mouse embryonic stem cells.

Author

Sladeček, Stanislava, Radaszkiewicz, Katarzyna Anna, Bőhmová, Martina, Gybeľ, Tomáš, Radaszkiewicz, Tomasz Witold, and Pacherník, Jiří

Subjects

*MESODERM, *EMBRYONIC stem cells, *EXTRACELLULAR signal-regulated kinases, *PROTEIN kinases, *EMBRYOLOGY, *MICE

Abstract

Dual specificity phosphatase 7 (DUSP7) is a protein belonging to a broad group of phosphatases that can dephosphorylate phosphoserine/phosphothreonine as well as phosphotyrosine residues within the same substrate. DUSP7 has been linked to the negative regulation of mitogen activated protein kinases (MAPK), and in particular to the regulation of extracellular signal-regulated kinases 1 and 2 (ERK1/2). MAPKs play an important role in embryonic development, where their duration, magnitude, and spatiotemporal activity must be strictly controlled by other proteins, among others by DUSPs. In this study, we focused on the effect of DUSP7 depletion on the in vitro differentiation of mouse embryonic stem (ES) cells. We showed that even though DUSP7 knock-out ES cells do retain some of their basic characteristics, when it comes to differentiation, they preferentially differentiate towards neural cells, while the formation of early cardiac mesoderm is repressed. Therefore, our data indicate that DUSP7 is necessary for the correct formation of neuroectoderm and cardiac mesoderm during the in vitro differentiation of ES cells. [ABSTRACT FROM AUTHOR]

Published

2022

20. Dynamical modeling of the H3K27 epigenetic landscape in mouse embryonic stem cells.

Author

Newar, Kapil, Abdulla, Amith Zafal, Salari, Hossein, Fanchon, Eric, and Jost, Daniel

Subjects

*EMBRYONIC stem cells, *HISTONES, *EPIGENETICS, *GENETIC regulation, *GENE silencing, *ENZYME regulation

Abstract

The Polycomb system via the methylation of the lysine 27 of histone H3 (H3K27) plays central roles in the silencing of many lineage-specific genes during development. Recent experimental evidence suggested that the recruitment of histone modifying enzymes like the Polycomb repressive complex 2 (PRC2) at specific sites and their spreading capacities from these sites are key to the establishment and maintenance of a proper epigenomic landscape around Polycomb-target genes. Here, to test whether such mechanisms, as a minimal set of qualitative rules, are quantitatively compatible with data, we developed a mathematical model that can predict the locus-specific distributions of H3K27 modifications based on previous biochemical knowledge. Within the biological context of mouse embryonic stem cells, our model showed quantitative agreement with experimental profiles of H3K27 acetylation and methylation around Polycomb-target genes in wild-type and mutants. In particular, we demonstrated the key role of the reader-writer module of PRC2 and of the competition between the binding of activating and repressing enzymes in shaping the H3K27 landscape around transcriptional start sites. The predicted dynamics of establishment and maintenance of the repressive trimethylated H3K27 state suggest a slow accumulation, in perfect agreement with experiments. Our approach represents a first step towards a quantitative description of PcG regulation in various cellular contexts and provides a generic framework to better characterize epigenetic regulation in normal or disease situations. Author summary: The regulation of gene expression in eucaryotes is in part regulated by specific biochemical modifications of chromatin, the so-called epigenetic marks. In particular, the Polycomb system deposits repressive marks that participate in the silencing of many genes during development. Recent experimental evidence suggested that the recruitment of specific enzymes (like PRC2) at dedicated genomic sites and their capacities to spread epigenetic marks from these sites are key to the functioning of the Polycomb repression. Here, we developed a mathematical model to test whether such mechanisms, as a minimal set of qualitative rules, are quantitatively compatible with data in mouse embryonic stem cells. We showed that the model well predicts the epigenetic landscape around repressed genes as well as the kinetics of its establishment and maintenance. We demonstrated the key role of the reader-writer module of PRC2 and of the competition between the binding of activating and repressing enzymes in Polycomb regulation. Our approach represents a first step towards a predictive description of epigenetic regulation in various cellular contexts. [ABSTRACT FROM AUTHOR]

Published

2022

21. Geneticin reduces mRNA stability.

Author

Durmaz, Yavuz T., Shatadal, Alankrit, and Friend, Kyle

Subjects

*MESSENGER RNA, *EMBRYONIC stem cells, *GENETIC code

Abstract

Messenger RNA (mRNA) translation can lead to higher rates of mRNA decay, suggesting the ribosome plays a role in mRNA destruction. Furthermore, mRNA features, such as codon identities, which are directly probed by the ribosome, correlate with mRNA decay rates. Many amino acids are encoded by synonymous codons, some of which are decoded by more abundant tRNAs leading to more optimal translation and increased mRNA stability. Variable translation rates for synonymous codons can lead to ribosomal collisions as ribosomes transit regions with suboptimal codons, and ribosomal collisions can promote mRNA decay. In addition to different translation rates, the presence of certain codons can also lead to higher or lower rates of amino acid misincorporation which could potentially lead to protein misfolding if a substituted amino acid fails to make critical contacts in a structure. Here, we test whether Geneticin—G418, an aminoglycoside antibiotic known to promote amino acid misincorporation—affects mRNA stability. We observe that G418 decreases firefly luciferase mRNA stability in an in vitro translation system and also reduces mRNA stability in mouse embryonic stem cells (mESCs). G418-sensitive mRNAs are enriched for certain optimal codons that contain G or C in the wobble position, arguing that G418 blunts the stabilizing effects of codon optimality. [ABSTRACT FROM AUTHOR]

Published

2022

22. Alternative splicing of METTL3 explains apparently METTL3-independent m6A modifications in mRNA.

Author

Poh, Hui Xian, Mirza, Aashiq H., Pickering, Brian F., and Jaffrey, Samie R.

Subjects

*ALTERNATIVE RNA splicing, *MESSENGER RNA, *EMBRYONIC stem cells, *CELL lines, *CRISPRS

Abstract

N6-methyladenosine (m6A) is a highly prevalent mRNA modification that promotes degradation of transcripts encoding proteins that have roles in cell development, differentiation, and other pathways. METTL3 is the major methyltransferase that catalyzes the formation of m6A in mRNA. As 30% to 80% of m6A can remain in mRNA after METTL3 depletion by CRISPR/Cas9-based methods, other enzymes are thought to catalyze a sizable fraction of m6A. Here, we reexamined the source of m6A in the mRNA transcriptome. We characterized mouse embryonic stem cell lines that continue to have m6A in their mRNA after Mettl3 knockout. We show that these cells express alternatively spliced Mettl3 transcript isoforms that bypass the CRISPR/Cas9 mutations and produce functionally active methyltransferases. We similarly show that other reported METTL3 knockout cell lines express altered METTL3 proteins. We find that gene dependency datasets show that most cell lines fail to proliferate after METTL3 deletion, suggesting that reported METTL3 knockout cell lines express altered METTL3 proteins rather than have full knockout. Finally, we reassessed METTL3's role in synthesizing m6A using an exon 4 deletion of Mettl3 and found that METTL3 is responsible for >95% of m6A in mRNA. Overall, these studies suggest that METTL3 is responsible for the vast majority of m6A in the transcriptome, and that remaining m6A in putative METTL3 knockout cell lines is due to the expression of altered but functional METTL3 isoforms. The modification m6A remains in mRNA after METTL3 depletion, suggesting that other m6A methyltransferases exist. This study investigates METTL3 knockouts, finding that they often escape knockout by expressing functional METTL3 hypomorphs, and demonstrating that METTL3 is indeed responsible for most m6A in mRNA. [ABSTRACT FROM AUTHOR]

Published

2022

23. Disaccharide-tag for highly sensitive identification of O-GlcNAc-modified proteins in mammalian cells.

Author

Abo, Hirohito, Kume, Masahiko, Pecori, Federico, Miura, Taichi, Matsumoto, Naoki, Nishihara, Shoko, and Yamamoto, Kazuo

Subjects

*PROTEOMICS, *LIQUID chromatography-mass spectrometry, *CYTOPLASM, *EMBRYONIC stem cells, *WHEAT germ, *TRANSCRIPTION factors

Abstract

O-GlcNAcylation is the only sugar modification for proteins present in the cytoplasm and nucleus and is thought to be involved in the regulation of protein function and localization. Currently, several methods are known for detecting O-GlcNAcylated proteins using monoclonal antibodies or wheat germ agglutinin, but these methods have some limitations in their sensitivity and quantitative comparison. We developed a new disaccharide-tag method to overcome these problems. This is a method in which a soluble GalNAc transferase is expressed intracellularly, extended to a disaccharide of GalNAc-GlcNAc, and detected using a Wisteria japonica agglutinin specific to this disaccharide. We verified the method using human c-Rel protein and also highly sensitively compared the difference in O-GlcNAc modification of intracellular proteins associated with differentiation from embryonic stem cell (ESC) to epiblast-like cells (EpiLC). As one example of such a modification, a novel O-GlcNAc modification was found in the transcription factor Sox2 at residue Ser263, and the modification site could be identified by nano liquid chromatography-mass spectrometry. [ABSTRACT FROM AUTHOR]

Published

2022

24. Transcriptome analysis reveals high tumor heterogeneity with respect to re-activation of stemness and proliferation programs.

Author

Baranovsky, Artem, Ivanov, Timofei, Granovskaya, Marina, Papatsenko, Dmitri, and Pervouchine, Dmitri D.

Subjects

*EMBRYONIC stem cells, *HETEROGENEITY, *TRANSCRIPTOMES, *MIRROR neurons, *CANCER cells, *STEM cells

Abstract

Significant alterations in signaling pathways and transcriptional regulatory programs together represent major hallmarks of many cancers. These, among all, include the reactivation of stemness, which is registered by the expression of pathways that are active in the embryonic stem cells (ESCs). Here, we assembled gene sets that reflect the stemness and proliferation signatures and used them to analyze a large panel of RNA-seq data from The Cancer Genome Atlas (TCGA) Consortium in order to specifically assess the expression of stemness-related and proliferation-related genes across a collection of different tumor types. We introduced a metric that captures the collective similarity of the expression profile of a tumor to that of ESCs, which showed that stemness and proliferation signatures vary greatly between different tumor types. We also observed a high degree of intertumoral heterogeneity in the expression of stemness- and proliferation-related genes, which was associated with increased hazard ratios in a fraction of tumors and mirrored by high intratumoral heterogeneity and a remarkable stemness capacity in metastatic lesions across cancer cells in single cell RNA-seq datasets. Taken together, these results indicate that the expression of stemness signatures is highly heterogeneous and cannot be used as a universal determinant of cancer. This calls into question the universal validity of diagnostic tests that are based on stem cell markers. [ABSTRACT FROM AUTHOR]

Published

2022

25. Use of standard U-bottom and V-bottom well plates to generate neuroepithelial embryoid bodies.

Author

Choy Buentello, David, Koch, Lena Sophie, Trujillo-de Santiago, Grissel, Alvarez, Mario Moisés, and Broersen, Kerensa

Subjects

*EMBRYONIC stem cells, *PLURIPOTENT stem cells

Abstract

The use of organoids has become increasingly popular recently due to their self-organizing abilities, which facilitate developmental and disease modeling. Various methods have been described to create embryoid bodies (EBs) generated from embryonic or pluripotent stem cells but with varying levels of differentiation success and producing organoids of variable size. Commercial ultra-low attachment (ULA) V-bottom well plates are frequently used to generate EBs. These plates are relatively expensive and not as widely available as standard concave well plates. Here, we describe a cost-effective and low labor-intensive method that creates homogeneous EBs at high yield in standard V- and U-bottom well plates by applying an anti-adherence solution to reduce surface attachment, followed by centrifugation to enhance cellular aggregation. We also explore the effect of different seeding densities, in the range of 1 to 11 ×103 cells per well, for the fabrication of neuroepithelial EBs. Our results show that the use of V-bottom well plates briefly treated with anti-adherent solution (for 5 min at room temperature) consistently yields functional neural EBs in the range of seeding densities from 5 to 11×103 cells per well. A brief post-seeding centrifugation step further enhances EB establishment. EBs fabricated using centrifugation exhibited lower variability in their final size than their non-centrifuged counterparts, and centrifugation also improved EB yield. The span of conditions for reliable EB production is narrower in U-bottom wells than in V-bottom wells (i.e., seeding densities between 7×103 and 11×103 and using a centrifugation step). We show that EBs generated by the protocols introduced here successfully developed into neural organoids and expressed the relevant markers associated with their lineages. We anticipate that the cost-effective and easily implemented protocols presented here will greatly facilitate the generation of EBs, thereby further democratizing the worldwide ability to conduct organoid-based research. [ABSTRACT FROM AUTHOR]

Published

2022

26. Normal embryonic development and neonatal digit regeneration in mice overexpressing a stem cell factor, Sall4.

Author

Chen, Katherine Q., Anderson, Aaron, Kawakami, Hiroko, Kim, Jennifer, Barrett, Janaya, and Kawakami, Yasuhiko

Subjects

*EMBRYOLOGY, *STEM cell factor, *REGENERATION (Biology), *EMBRYONIC stem cells, *GENETIC overexpression

Abstract

Sall4 encodes a transcription factor and is known to participate in the pluripotency network of embryonic stem cells. Sall4 expression is known to be high in early stage post-implantation mouse embryos. During early post-gastrulation stages, Sall4 is highly expressed in the tail bud and distal limb buds, where progenitor cells are maintained in an undifferentiated status. The expression of Sall4 is rapidly downregulated during embryonic development. We previously demonstrated that Sall4 is required for limb and posterior axial skeleton development by conditional deletion of Sall4 in the T (Brachyury) lineage. To gain insight into Sall4 functions in embryonic development and postnatal digit regeneration, we genetically overexpressed Sall4 in the mesodermal lineage by the TCre transgene and a novel knockin allele of Rosa26-loxP-stop-loxP-Sall4. In significant contrast to severe defects by Sall4 loss of function reported in previous studies, overexpression of Sall4 resulted in normal morphology and pattern in embryos and neonates. The length of limb long bones showed subtle reduction in Sall4-overexpression mice. It is known that the digit tip of neonatal mice has level-specific regenerative ability after experimental amputation. We observed Sall4 expression in the digit tip by using a sensitive Sall4-LacZ knock-in reporter expression. Sall4 overexpression did not alter the regenerative ability of the terminal phalange that normally regenerates after amputation. Moreover, Sall4 overexpression did not confer regenerative ability to the second phalange that normally does not regenerate after amputation. These genetic experiments show that overexpression of Sall4 does not alter the development of the appendicular and axial skeleton, or neonatal digit regeneration. The results suggest that Sall4 acts as a permissive factor rather than playing an instructive role. [ABSTRACT FROM AUTHOR]

Published

2022

27. Gain-of-function mutations in Trim71 linked to congenital hydrocephalus.

Author

Chen, Yingying, Yang, Xianfa, and Jing, Naihe

Subjects

*GAIN-of-function mutations, *WNT signal transduction, *HYDROCEPHALUS, *EMBRYONIC stem cells

Abstract

The genetic basis of congenital hydrocephalus is only partially understood. A new study in PLOS Biology reports a potential gain-of-function pathological mechanism of congenital hydrocephalus in mouse embryonic stem cells that involves Wnt–β-catenin signaling pathway regulation. Mutations in the RNA-binding domain of Trim71 can cause congenital hydrocephalus (CH). This Primer explores a recent study in PLOS Biology which shows that two known CH-associated Trim71 mutations lead to distinct ectopic RNA binding; these gain-of-function mechanisms influence neurogenesis in vitro and may contribute to CH pathology. [ABSTRACT FROM AUTHOR]

Published

2023

28. Chronic spinal cord injury functionally repaired by direct implantation of encapsulated hair-follicle-associated pluripotent (HAP) stem cells in a mouse model: Potential for clinical regenerative medicine.

Author

Obara, Koya, Shirai, Kyoumi, Hamada, Yuko, Arakawa, Nobuko, Yamane, Michiko, Takaoka, Nanako, Aki, Ryoichi, Hoffman, Robert M., and Amoh, Yasuyuki

Subjects

*STEM cells, *SPINAL cord injuries, *EMBRYONIC stem cells, *HAIR follicles, *PLURIPOTENT stem cells, *REGENERATIVE medicine, *NEURAL stem cells

Abstract

Chronic spinal cord injury (SCI) is a highly debilitating and recalcitrant disease with limited treatment options. Although various stem cell types have shown some clinical efficacy for injury repair they have not for SCI. Hair-follicle-associated pluripotent (HAP) stem cells have been shown to differentiate into neurons, Schwan cells, beating cardiomyocytes and many other type of cells, and have effectively regenerated acute spinal cord injury in mouse models. In the present report, HAP stem cells from C57BL/6J mice, encapsulated in polyvinylidene fluoride membranes (PFM), were implanted into the severed thoracic spinal cord of C57BL/6J or athymic nude mice in the early chronic phase. After implantation, HAP stem cells differentiated to neurons, astrocytes and oligodendrocytes in the regenerated thoracic spinal cord of C57BL/6J and nude mice. Quantitative motor function analysis, with the Basso Mouse Scale for Locomotion (BMS) score, demonstrated a significant functional improvement in the HAP-stem-cell-implanted mice, compared to non-implanted mice. HAP stem cells have critical advantages over other stem cells: they do not develop teratomas; do not loose differentiation ability when cryopreserved and thus are bankable; are autologous, readily obtained from anyone; and do not require genetic manipulation. HAP stem cells therefore have greater clinical potential for SCI repair than induced pluripotent stem cells (iPSCs), neuronal stem cells (NSCs)/neural progenitor cells (NPCs) or embryonic stem cells (ESCs). The present report demonstrates future clinical potential of HAP-stem-cell repair of chronic spinal cord injury, currently a recalcitrant disease. [ABSTRACT FROM AUTHOR]

Published

2022

29. P63 targeted deletion under the FOXN1 promoter disrupts pre-and post-natal thymus development, function and maintenance as well as induces severe hair loss.

Author

Stefanski, Heather E., Xing, Yan, Nicholls, Jemma, Jonart, Leslie, Goren, Emily, Taylor, Patricia A., Mills, Alea A., Riddle, Megan, McGrath, John, Tolar, Jakub, Hollander, Georg A., and Blazar, Bruce R.

Subjects

*T cells, *BALDNESS, *HAIR follicles, *EMBRYONIC stem cells, *THYMUS, *EMBRYOLOGY, *GENERATING functions

Abstract

Progressive immune deficiency of aging is characterized by severe thymic atrophy, contracted T cell repertoire, and poor immune function. p63 is critical for the proliferative potential of embryonic and adult stem cells, as well as thymic epithelial cells (TECs). Because p63 null mice experience rapid post-natal lethality due to epidermal and limb morphogenesis defects, studies to define a role for p63 expression in TEC biology focused on embryonic thymus development and in vitro experiments. Since post-natal thymic stromal development and function differs from that of the embryo, we assessed the impact of lineage-restricted p63 loss on pre- and post-natal murine TEC function by generating mice with a loss of p63 function targeted to TEC, termed p63TECko mice. In adult p63TECko mice, severe thymic hypoplasia was observed with a lack in a discernable segregation into medullary and cortical compartments and peripheral T cell lymphopenia. This profound thymic defect was seen in both neonatal as well as embryonic p63TECko mice. In addition to TECs, p63 also plays in important role in the development of stratified epithelium of the skin; lack of p63 results in defects in skin epidermal stratification and differentiation. Interestingly, all adult p63TECko mice lacked hair follicles despite having normal p63 expression in the skin. Together our results show a critical role of TEC p63 in thymic development and maintenance and show that p63 expression is critical for hair follicle formation. [ABSTRACT FROM AUTHOR]

Published

2022

30. Scalable in vitro production of defined mouse erythroblasts.

Author

Francis, Helena S., Harold, Caroline L., Beagrie, Robert A., King, Andrew J., Gosden, Matthew E., Blayney, Joseph W., Jeziorska, Danuta M., Babbs, Christian, Higgs, Douglas R., and Kassouf, Mira T.

Subjects

*MICE, *ERYTHROPOIESIS, *ERYTHROCYTE membranes, *EMBRYONIC stem cells, *LABORATORY mice

Abstract

Mouse embryonic stem cells (mESCs) can be manipulated in vitro to recapitulate the process of erythropoiesis, during which multipotent cells undergo lineage specification, differentiation and maturation to produce erythroid cells. Although useful for identifying specific progenitors and precursors, this system has not been fully exploited as a source of cells to analyse erythropoiesis. Here, we establish a protocol in which characterised erythroblasts can be isolated in a scalable manner from differentiated embryoid bodies (EBs). Using transcriptional and epigenetic analysis, we demonstrate that this system faithfully recapitulates normal primitive erythropoiesis and fully reproduces the effects of natural and engineered mutations seen in primary cells obtained from mouse models. We anticipate this system to be of great value in reducing the time and costs of generating and maintaining mouse lines in a number of research scenarios. [ABSTRACT FROM AUTHOR]

Published

2022

31. DNMT1 regulates the timing of DNA methylation by DNMT3 in an enzymatic activity-dependent manner in mouse embryonic stem cells.

Author

Ito, Takamasa, Kubiura-Ichimaru, Musashi, Murakami, Yuri, Bogutz, Aaron B., Lefebvre, Louis, Suetake, Isao, Tajima, Shoji, and Tada, Masako

Subjects

*EMBRYONIC stem cells, *DNA methylation, *DNA methyltransferases, *PHYSIOLOGY, *DNA replication, *MICE

Abstract

DNA methylation (DNAme; 5-methylcytosine, 5mC) plays an essential role in mammalian development, and the 5mC profile is regulated by a balance of opposing enzymatic activities: DNA methyltransferases (DNMTs) and Ten-eleven translocation dioxygenases (TETs). In mouse embryonic stem cells (ESCs), de novo DNAme by DNMT3 family enzymes, demethylation by the TET-mediated conversion of 5mC to 5-hydroxymethylation (5hmC), and maintenance of the remaining DNAme by DNMT1 are actively repeated throughout cell cycles, dynamically forming a constant 5mC profile. Nevertheless, the detailed mechanism and physiological significance of this active cyclic DNA modification in mouse ESCs remain unclear. Here by visualizing the localization of DNA modifications on metaphase chromosomes and comparing whole-genome methylation profiles before and after the mid-S phase in ESCs lacking Dnmt1 (1KO ESCs), we demonstrated that in 1KO ESCs, DNMT3-mediated remethylation was interrupted during and after DNA replication. This results in a marked asymmetry in the distribution of 5hmC between sister chromatids at mitosis, with one chromatid being almost no 5hmC. When introduced in 1KO ESCs, the catalytically inactive form of DNMT1 (DNMT1CI) induced an increase in DNAme in pericentric heterochromatin and the DNAme-independent repression of IAPEz, a retrotransposon family, in 1KO ESCs. However, DNMT1CI could not restore the ability of DNMT3 to methylate unmodified dsDNA de novo in S phase in 1KO ESCs. Furthermore, during in vitro differentiation into epiblasts, 1KO ESCs expressing DNMT1CI showed an even stronger tendency to differentiate into the primitive endoderm than 1KO ESCs and were readily reprogrammed into the primitive streak via an epiblast-like cell state, reconfirming the importance of DNMT1 enzymatic activity at the onset of epiblast differentiation. These results indicate a novel function of DNMT1, in which DNMT1 actively regulates the timing and genomic targets of de novo methylation by DNMT3 in an enzymatic activity-dependent and independent manner, respectively. [ABSTRACT FROM AUTHOR]

Published

2022

32. A conserved expression signature predicts growth rate and reveals cell & lineage-specific differences.

Author

Jiang, Zhisheng, Generoso, Serena F., Badia, Marta, Payer, Bernhard, and Carey, Lucas B.

Subjects

*EMBRYONIC stem cells, *PROTEOLYSIS, *PLURIPOTENT stem cells, *EUKARYOTIC cells, *CAENORHABDITIS elegans

Abstract

Isogenic cells cultured together show heterogeneity in their proliferation rate. To determine the differences between fast and slow-proliferating cells, we developed a method to sort cells by proliferation rate, and performed RNA-seq on slow and fast proliferating subpopulations of pluripotent mouse embryonic stem cells (mESCs) and mouse fibroblasts. We found that slowly proliferating mESCs have a more naïve pluripotent character. We identified an evolutionarily conserved proliferation-correlated transcriptomic signature that is common to all eukaryotes: fast cells have higher expression of genes for protein synthesis and protein degradation. This signature accurately predicted growth rate in yeast and cancer cells, and identified lineage-specific proliferation dynamics during development, using C. elegans scRNA-seq data. In contrast, sorting by mitochondria membrane potential revealed a highly cell-type specific mitochondria-state related transcriptome. mESCs with hyperpolarized mitochondria are fast proliferating, while the opposite is true for fibroblasts. The mitochondrial electron transport chain inhibitor antimycin affected slow and fast subpopulations differently. While a major transcriptional-signature associated with cell-to-cell heterogeneity in proliferation is conserved, the metabolic and energetic dependency of cell proliferation is cell-type specific. Author summary: By performing RNA sequencing on cells sorted by their proliferation rate, this study identifies a gene expression signature capable of predicting proliferation rates in diverse eukaryotic cell types and species. This signature, applied to single-cell RNA sequencing data from embryos of the roundworm C. elegans, reveals lineage-specific proliferation differences during development. In contrast to the universality of the proliferation signature, mitochondria and metabolism related genes show a high degree of cell-type specificity; mouse pluripotent stem cells (mESCs) and differentiated cells (fibroblasts) exhibit opposite relations between mitochondria state and proliferation. Furthermore, we identified a slow proliferating subpopulation of mESCs with higher expression of pluripotency genes. Finally, we show that fast and slow proliferating subpopulations are differentially sensitive to mitochondria inhibitory drugs in different cell types. Highlights: A FACS-based method to determine the transcriptomes of fast and slow proliferating subpopulations. A universal proliferation-correlated transcriptional signature indicates high protein synthesis and degradation in fast proliferating cells across cell types and species. Applied to scRNA-seq, the expression signature predicts the global proliferation slowdown during C. elegans development. Mitochondria membrane potential predicts proliferation rate in a cell-type specific manner, with ETC complex III inhibitor having distinct effects on fibroblasts vs mESCs. [ABSTRACT FROM AUTHOR]

Published

2021

33. Deciphering the molecular mechanism of the cancer formation by chromosome structural dynamics.

Author

Chu, Xiakun and Wang, Jin

Subjects

*STRUCTURAL dynamics, *GENE regulatory networks, *CANCER cell differentiation, *CHROMOSOMES, *EMBRYONIC stem cells

Abstract

Cancer reflects the dysregulation of the underlying gene network, which is strongly related to the 3D genome organization. Numerous efforts have been spent on experimental characterizations of the structural alterations in cancer genomes. However, there is still a lack of genomic structural-level understanding of the temporal dynamics for cancer initiation and progression. Here, we use a landscape-switching model to investigate the chromosome structural transition during the cancerization and reversion processes. We find that the chromosome undergoes a non-monotonic structural shape-changing pathway with initial expansion followed by compaction during both of these processes. Furthermore, our analysis reveals that the chromosome with a more expanding structure than those at both the normal and cancer cell during cancerization exhibits a sparse contact pattern, which shows significant structural similarity to the one at the embryonic stem cell in many aspects, including the trend of contact probability declining with the genomic distance, the global structural shape geometry and the spatial distribution of loci on the chromosome. In light of the intimate structure-function relationship at the chromosomal level, we further describe the cell state transition processes by the chromosome structural changes, suggesting an elevated cell stemness during the formation of the cancer cells. We show that cell cancerization and reversion are highly irreversible processes in terms of the chromosome structural transition pathways, spatial repositioning of chromosomal loci and hysteresis loop of contact evolution analysis. Our model draws a molecular-scale picture of cell cancerization from the chromosome structural perspective. The process contains initial reprogramming towards the stem cell followed by the differentiation towards the cancer cell, accompanied by an initial increase and subsequent decrease of the cell stemness. Author summary: Cancer is among the leading causes of human death. Cancer is regulated by the underlying regulatory network of gene expressions, which are in intimate relation to the 3D chromosome architectures. Numerous efforts have been spent on elucidating the chromosome structural variants in tumorigenesis, while the dynamical picture of how chromosomes structurally evolve during cancer formation is still missing. Here we integrate the Hi-C data into the polymer simulations to build the chromosome structural ensembles in the normal and cancer cells. Then we use a nonequilibrium landscape-switching model to simulate the chromosome structural dynamics during the cancerization and reversion processes. With quantified pathways, we show that the chromosomes at transient intermediate states in the cancer formation possess a significant degree of structural similarity to those at the stem cell. Our findings indicate the formation of stem-like states during cancer formation from the chromosome structural perspective. We draw a molecular-scale picture of the cancer formation, which contains initial reprogramming towards the stem cell followed by differentiation towards the cancer cell. [ABSTRACT FROM AUTHOR]

Published

2021

34. Kaposi's sarcoma-associated herpesvirus promotes mesenchymal-to-endothelial transition by resolving the bivalent chromatin of PROX1 gene.

Author

Ding, Yao, Chen, Weikang, Lu, Zhengzhou, Wang, Yan, and Yuan, Yan

Subjects

*KAPOSI'S sarcoma-associated herpesvirus, *KAPOSI'S sarcoma, *CHROMATIN, *HOMEOBOX genes, *EMBRYONIC stem cells

Abstract

Increasing evidence suggests that Kaposi's sarcoma (KS) arises from Kaposi's sarcoma-associated herpesvirus (KSHV)-infected mesenchymal stem cells (MSCs) through mesenchymal-to-endothelial transition (MEndT). KSHV infection promotes MSC differentiation of endothelial lineage and acquisition of tumorigeneic phenotypes. To understand how KSHV induces MEndT and transforms MSCs to KS cells, we investigated the mechanism underlying KSHV-mediated MSC endothelial lineage differentiation. Like embryonic stem cells, MSC differentiation and fate determination are under epigenetic control. Prospero homeobox 1 (PROX1) is a master regulator that controls lymphatic vessel development and endothelial differentiation. We found that the PROX1 gene in MSCs harbors a distinctive bivalent epigenetic signature consisting of both active marker H3K4me3 and repressive marker H3K27me3, which poises expression of the genes, allowing timely activation upon differentiation signals or environmental stimuli. KSHV infection effectively resolves the bivalent chromatin by decreasing H3K27me3 and increasing H3K4me3 to activate the PROX1 gene. vIL-6 signaling leads to the recruitment of MLL2 and SET1 complexes to the PROX1 promoter to increase H3K4me3, and the vGPCR-VEGF-A axis is responsible for removing PRC2 from the promoter to reduce H3K27me3. Therefore, through a dual signaling process, KSHV activates PROX1 gene expression and initiates MEndT, which renders MSC tumorigenic features including angiogenesis, invasion and migration. Author summary: Numerous parallelisms between development and cancer led to the concept that cancer is a development problem over the past 50 years. As our knowledge of epigenetic regulation is advancing, the similarities between development and cancer are becoming more apparent, providing further support to the theory. KSHV infection of mesenchymal stem cells (MSCs) may result in Kaposi's sarcoma (KS) through mesenchymal-to-endothelial transition (MEndT), a process resembling endothelial differentiation during development. KSHV initiates MEndT by activating the homeobox gene PROX1, a master regulator of the lymphatic endothelial cell differentiation, at the epigenetic level. Here we found that the PROX1 gene resides in bivalent domain chromatin in MSCs and KSHV infection resolves it through a dual signaling process to activates the PROX1 gene, which initiates MEndT and confers MSC KS-like phenotypes. The significance of this study is two-fold. First, the study elucidated the mechanism underlying KSHV-mediated MEndT and KS development at the transcription level. Second, KSHV uses two independent pathways to elevate activating histone modification and decrease repressive marker, respectively, to resolved bivalent chromatin, revealing a two-factor-authentication mechanism in the epigenetic regulation, which may grant a more efficient and accurate response to activate a gene in bivalent chromatin. [ABSTRACT FROM AUTHOR]

Published

2021

35. Synthetic modified Fezf2 mRNA (modRNA) with concurrent small molecule SIRT1 inhibition enhances refinement of cortical subcerebral/corticospinal neuron identity from mouse embryonic stem cells.

Author

Sadegh, Cameron, Ebina, Wataru, Arvanites, Anthony C., Davidow, Lance S., Rubin, Lee L., and Macklis, Jeffrey D.

Subjects

*EMBRYONIC stem cells, *SIRTUINS, *SMALL molecules, *CEREBRAL cortex development, *NEURAL stem cells, *PLURIPOTENT stem cells

Abstract

During late embryonic development of the cerebral cortex, the major class of cortical output neurons termed subcerebral projection neurons (SCPN; including the predominant population of corticospinal neurons, CSN) and the class of interhemispheric callosal projection neurons (CPN) initially express overlapping molecular controls that later undergo subtype-specific refinements. Such molecular refinements are largely absent in heterogeneous, maturation-stalled, neocortical-like neurons (termed "cortical" here) spontaneously generated by established embryonic stem cell (ES) and induced pluripotent stem cell (iPSC) differentiation. Building on recently identified central molecular controls over SCPN development, we used a combination of synthetic modified mRNA (modRNA) for Fezf2, the central transcription factor controlling SCPN specification, and small molecule screening to investigate whether distinct chromatin modifiers might complement Fezf2 functions to promote SCPN-specific differentiation by mouse ES (mES)-derived cortical-like neurons. We find that the inhibition of a specific histone deacetylase, Sirtuin 1 (SIRT1), enhances refinement of SCPN subtype molecular identity by both mES-derived cortical-like neurons and primary dissociated E12.5 mouse cortical neurons. In vivo, we identify that SIRT1 is specifically expressed by CPN, but not SCPN, during late embryonic and postnatal differentiation. Together, these data indicate that SIRT1 has neuronal subtype-specific expression in the mouse cortex in vivo, and that its inhibition enhances subtype-specific differentiation of highly clinically relevant SCPN / CSN cortical neurons in vitro. [ABSTRACT FROM AUTHOR]

Published

2021

36. SUMO conjugation susceptibility of Akt/protein kinase B affects the expression of the pluripotency transcription factor Nanog in embryonic stem cells.

Author

Francia, Marcos, Stortz, Martin, Echegaray, Camila Vazquez, Oses, Camila, Verneri, Paula, Petrone, María Victoria, Toro, Ayelen, Waisman, Ariel, Miriuka, Santiago, Cosentino, María Soledad, Levi, Valeria, and Guberman, Alejandra

Subjects

*PROTEIN kinase B, *EMBRYONIC stem cells, *TRANSCRIPTION factors, *SOX2 protein, *POST-translational modification, *KINASE regulation

Abstract

Akt/PKB is a kinase involved in the regulation of a wide variety of cell processes. Its activity is modulated by diverse post-translational modifications (PTMs). Particularly, conjugation of the small ubiquitin-related modifier (SUMO) to this kinase impacts on multiple cellular functions, such as proliferation and splicing. In embryonic stem (ES) cells, this kinase is key for pluripotency maintenance. Among other functions, Akt is known to promote the expression of Nanog, a central pluripotency transcription factor (TF). However, the relevance of this specific PTM of Akt has not been previously analyzed in this context. In this work, we study the effect of Akt1 variants with differential SUMOylation susceptibility on the expression of Nanog. Our results demonstrate that both, the Akt1 capability of being modified by SUMO conjugation and a functional SUMO conjugase activity are required to induce Nanog gene expression. Likewise, we found that the common oncogenic E17K Akt1 mutant affected Nanog expression in ES cells also in a SUMOylatability dependent manner. Interestingly, this outcome takes places in ES cells but not in a non-pluripotent heterologous system, suggesting the presence of a crucial factor for this induction in ES cells. Remarkably, the two major candidate factors to mediate this induction, GSK3-β and Tbx3, are non-essential players of this effect, suggesting a complex mechanism probably involving non-canonical pathways. Furthermore, we found that Akt1 subcellular distribution does not depend on its SUMOylatability, indicating that Akt localization has no influence on the effect on Nanog, and that besides the membrane localization of E17K Akt mutant, SUMOylation is also required for its hyperactivity. Our results highlight the impact of SUMO conjugation in the function of a kinase relevant for a plethora of cellular processes, including the control of a key pluripotency TF. [ABSTRACT FROM AUTHOR]

Published

2021

37. Multivariate meta-analysis reveals global transcriptomic signatures underlying distinct human naive-like pluripotent states.

Author

Johnson, Kory R., Mallon, Barbara S., Fann, Yang C., and Chen, Kevin G.

Subjects

*EMBRYONIC stem cells, *PLURIPOTENT stem cells, *HUMAN stem cells, *META-analysis, *PRINCIPAL components analysis

Abstract

The ground or naive pluripotent state of human pluripotent stem cells (hPSCs), which was initially established in mouse embryonic stem cells (mESCs), is an emerging and tentative concept. To verify this vital concept in hPSCs, we performed a multivariate meta-analysis of major hPSC datasets via the combined analytic powers of percentile normalization, principal component analysis (PCA), t-distributed stochastic neighbor embedding (t-SNE), and SC3 consensus clustering. This robust bioinformatics approach has significantly improved the predictive values of our meta-analysis. Accordingly, we revealed various similarities or dissimilarities between some naive-like hPSCs (NLPs) generated from different laboratories. Our analysis confirms some previous studies and provides new evidence concerning the existence of three distinct naive-like pluripotent states. Moreover, our study offers global transcriptomic markers that define diverse pluripotent states under various hPSC growth protocols. [ABSTRACT FROM AUTHOR]

Published

2021

38. Heat shock response enhanced by cell culture treatment in mouse embryonic stem cell-derived proliferating neural stem cells.

Author

Omori, Hiroyuki, Otsu, Masahiro, Nogami, Haruo, and Shibata, Masayoshi

Subjects

*NEURAL stem cells, *CELL culture, *NEUROGLIA, *CELL death, *EMBRYONIC stem cells, MECHANICAL shock measurement

Abstract

Cells have a regulatory mechanism known as heat shock (HS) response, which induces the expression of HS genes and proteins in response to heat and other cellular stresses. Exposure to moderate HS results in beneficial effects, such as thermotolerance and promotes survival, whereas excessive HS causes cell death. The effect of HS on cells depends on both exogenous factors, including the temperature and duration of heat application, and endogenous factors, such as the degree of cell differentiation. Neural stem cells (NSCs) can self-renew and differentiate into neurons and glial cells, but the changes in the HS response of symmetrically proliferating NSCs in culture are unclear. We evaluated the HS response of homogeneous proliferating NSCs derived from mouse embryonic stem cells during the proliferative phase and its effect on survival and cell death in vitro. The number of adherent cells and the expression ratios of HS protein (Hsp)40 and Hsp70 genes after exposure to HS for 20 min at temperatures above 43°C significantly increased with the extension of the culture period before exposure to HS. In contrast, caspase activity was significantly decreased by extension of the culture period before exposure to HS and suppressed the decrease in cell viability. These results suggest that the culture period before HS remarkably affects the HS response, influencing the expression of HS genes and cell survival of proliferating NSCs in culture. [ABSTRACT FROM AUTHOR]

Published

2021

39. DNA methylation patterns expose variations in enhancer-chromatin modifications during embryonic stem cell differentiation.

Author

Alajem, Adi, Roth, Hava, Ratgauzer, Sofia, Bavli, Danny, Motzik, Alex, Lahav, Shlomtzion, Peled, Itay, and Ram, Oren

Subjects

*DNA methylation, *EMBRYONIC stem cells, *GENE enhancers, *CELL differentiation, *BIOLOGICAL systems, *GENES, *HISTONES

Abstract

In mammals, cellular identity is defined through strict regulation of chromatin modifications and DNA methylation that control gene expression. Methylation of cytosines at CpG sites in the genome is mainly associated with suppression; however, the reason for enhancer-specific methylation is not fully understood. We used sequential ChIP-bisulfite-sequencing for H13K4me1 and H3K27ac histone marks. By collecting data from the same genomic region, we identified enhancers differentially methylated between these two marks. We observed a global gain of CpG methylation primarily in H3K4me1-marked nucleosomes during mouse embryonic stem cell differentiation. This gain occurred largely in enhancer regions that regulate genes critical for differentiation. The higher levels of DNA methylation in H3K4me1- versus H3K27ac-marked enhancers, despite it being the same genomic region, indicates cellular heterogeneity of enhancer states. Analysis of single-cell RNA-seq profiles demonstrated that this heterogeneity correlates with gene expression during differentiation. Furthermore, heterogeneity of enhancer methylation correlates with transcription start site methylation. Our results provide insights into enhancer-based functional variation in complex biological systems. Author summary: Cellular dynamics are underlined by numerous regulatory layers. The regulatory mechanism of interest in this work are enhancers. Enhancers are regulatory regions responsible, mainly, for increasing the possibility of transcription of a certain gene. Enhancers are marked by two distinct chemical groups-H3K4me1 and H3K27ac on the tail of histones. Histones are the proteins responsible for DNA packaging into condensed chromatin structure. In contrast, DNA methylation is a chemical modification often found on enhancers, and is traditionally associated with repression. A long-debated question revolves around the functional relevance of DNA methylation in the context of enhancers. Here, we combined the two regulatory layers, histone marks and DNA methylation, to a single measurement that can highlight DNA methylation separately on each histone mark but at the same genomic region. When isolated with H3K4me1, enhancers showed higher levels of methylation compared to H3K27ac. As we measured the same genomic locations, we show that differences of DNA methylation between these marks can only be explained by cellular heterogeneity. We also demonstrated that these enhancers tend to play roles in stem cell differentiation and expression levels of the genes they control correlate with cell-to-cell variation. [ABSTRACT FROM AUTHOR]

Published

2021

40. A cohesin cancer mutation reveals a role for the hinge domain in genome organization and gene expression.

Author

Carico, Zachary M., Stefan, Holden C., Justice, Megan, Yimit, Askar, and Dowen, Jill M.

Subjects

*COHESINS, *GENE expression, *EMBRYONIC stem cells, *GENETIC mutation, *ACUTE myeloid leukemia, *DNA folding

Abstract

The cohesin complex spatially organizes interphase chromatin by bringing distal genomic loci into close physical proximity, looping out the intervening DNA. Mutation of cohesin complex subunits is observed in cancer and developmental disorders, but the mechanisms through which these mutations may contribute to disease remain poorly understood. Here, we investigate a recurrent missense mutation to the hinge domain of the cohesin subunit SMC1A, observed in acute myeloid leukemia. Engineering this mutation into murine embryonic stem cells caused widespread changes in gene expression, including dysregulation of the pluripotency gene expression program. This mutation reduced cohesin levels at promoters and enhancers, decreased DNA loops and interactions across short genomic distances, and weakened insulation at CTCF-mediated DNA loops. These findings provide insight into how altered cohesin function contributes to disease and identify a requirement for the cohesin hinge domain in three-dimensional chromatin structure. Author summary: Mammalian genomes consist of multiple meters of DNA which must be highly folded in order to fit inside of the nucleus. This folding is regulated at multiple scales by different biological mechanisms. The spatial organization of the genome is closely linked to its function, including the spatial and temporal expression of genes. Especially important for gene control is the partitioning of chromosomes into DNA loops, which are formed when two distal loci are brought into close contact. The folding of the genome into DNA loops is performed by cohesin and CTCF. The molecular basis for how DNA loops dynamically form and function in gene control is poorly understood. Here, we investigate a recurrent cancer mutation in cohesin and show that it causes altered folding of the genome into DNA loops and misexpression of many genes. This finding is important because cohesin mutations are common in many cancers and yet there is little understanding of how cohesin defects may contribute to disease. [ABSTRACT FROM AUTHOR]

Published

2021

41. On the role of transcription in positioning nucleosomes.

Author

Jiang, Zhongling and Zhang, Bin

Subjects

*NUCLEOTIDE sequence, *EMBRYONIC stem cells, *CHROMATIN, *CARRIER proteins, *PHASED array antennas, *TRANSCRIPTION factors, *HISTONES

Abstract

Nucleosome positioning is crucial for the genome's function. Though the role of DNA sequence in positioning nucleosomes is well understood, a detailed mechanistic understanding on the impact of transcription remains lacking. Using numerical simulations, we investigated the dependence of nucleosome density profiles on transcription level across multiple species. We found that the low nucleosome affinity of yeast, but not mouse, promoters contributes to the formation of phased nucleosomes arrays for inactive genes. For the active genes, a heterogeneous distribution of +1 nucleosomes, caused by a tug-of-war between two types of remodeling enzymes, is essential for reproducing their density profiles. In particular, while positioning enzymes are known to remodel the +1 nucleosome and align it toward the transcription start site (TSS), spacer enzymes that use a pair of nucleosomes as their substrate can shift the nucleosome array away from the TSS. Competition between these enzymes results in two types of nucleosome density profiles with well- and ill-positioned +1 nucleosome. Finally, we showed that Pol II assisted histone exchange, if occurring at a fast speed, can abolish the impact of remodeling enzymes. By elucidating the role of individual factors, our study reconciles the seemingly conflicting results on the overall impact of transcription in positioning nucleosomes across species. Author summary: Nucleosome positioning plays a key role in the genome's function by regulating the accessibility of protein binding sites as well as higher-order chromatin organization. Though significant progress has been made towards studying the role of DNA sequence in positioning the nucleosomes, our understanding on the impact of transcription lags behind. Our study uses kinetic simulations to explore the role of DNA sequence specificity, transcription factor binding, enzyme remodeling, and Pol II elongation in positioning nucleosomes. It suggests that the differences in nucleosome density profiles observed at various transcription levels in yeast and mouse embryonic stem cells can be understood from a tug-of-war between two types of remodeling enzymes. [ABSTRACT FROM AUTHOR]

Published

2021

42. Machine learning based CRISPR gRNA design for therapeutic exon skipping.

Author

Louie, Wilson, Shen, Max W., Tahiry, Zakir, Zhang, Sophia, Worstell, Daniel, Cassa, Christopher A., Sherwood, Richard I., and Gifford, David K.

Subjects

*MACHINE learning, *EMBRYONIC stem cells, *CRISPRS, *EXONS (Genetics), *GENOME editing

Abstract

Restoring gene function by the induced skipping of deleterious exons has been shown to be effective for treating genetic disorders. However, many of the clinically successful therapies for exon skipping are transient oligonucleotide-based treatments that require frequent dosing. CRISPR-Cas9 based genome editing that causes exon skipping is a promising therapeutic modality that may offer permanent alleviation of genetic disease. We show that machine learning can select Cas9 guide RNAs that disrupt splice acceptors and cause the skipping of targeted exons. We experimentally measured the exon skipping frequencies of a diverse genome-integrated library of 791 splice sequences targeted by 1,063 guide RNAs in mouse embryonic stem cells. We found that our method, SkipGuide, is able to identify effective guide RNAs with a precision of 0.68 (50% threshold predicted exon skipping frequency) and 0.93 (70% threshold predicted exon skipping frequency). We anticipate that SkipGuide will be useful for selecting guide RNA candidates for evaluation of CRISPR-Cas9-mediated exon skipping therapy. Author summary: One form of genetic therapy is exon skipping, where a cell is forced to exclude problematic exons from a mutant transcript such that the resultant protein is functional. Recent studies show that CRISPR technology can induce therapeutic exon skipping. By using a specific guide RNA, targeted disruption of an exon's splice acceptor sequence can be performed, which can result in its skipping. However, an exon may have many candidate guide RNAs that target its splice acceptor, and not all guide RNAs will lead to a sufficient level of exon skipping. A predictive method that can identify a guide RNA that will cause an exon to be skipped would be useful for guiding therapeutic development efforts. We present SkipGuide, a machine learning method for predicting the exon skipping level caused by a guide RNA that targets its splice acceptor region. To develop and evaluate SkipGuide, we experimentally measured the skipping levels of a diverse set of exons targeted by multiple guide RNAs in a mouse cell line. We demonstrate that SkipGuide can accurately identify the guide RNAs that lead to high levels of exon skipping. [ABSTRACT FROM AUTHOR]

Published

2021

43. Single-cell RNA-seq analysis of mouse preimplantation embryos by third-generation sequencing.

Author

Fan, Xiaoying, Tang, Dong, Liao, Yuhan, Li, Pidong, Zhang, Yu, Wang, Minxia, Liang, Fan, Wang, Xiao, Gao, Yun, Wen, Lu, Wang, Depeng, Wang, Yang, and Tang, Fuchou

Subjects

*EMBRYONIC stem cells, *RNA sequencing, *EMBRYOS, *MICE, *GENE expression

Abstract

The development of next generation sequencing (NGS) platform-based single-cell RNA sequencing (scRNA-seq) techniques has tremendously changed biological researches, while there are still many questions that cannot be addressed by them due to their short read lengths. We developed a novel scRNA-seq technology based on third-generation sequencing (TGS) platform (single-cell amplification and sequencing of full-length RNAs by Nanopore platform, SCAN-seq). SCAN-seq exhibited high sensitivity and accuracy comparable to NGS platform-based scRNA-seq methods. Moreover, we captured thousands of unannotated transcripts of diverse types, with high verification rate by reverse transcription PCR (RT-PCR)–coupled Sanger sequencing in mouse embryonic stem cells (mESCs). Then, we used SCAN-seq to analyze the mouse preimplantation embryos. We could clearly distinguish cells at different developmental stages, and a total of 27,250 unannotated transcripts from 9,338 genes were identified, with many of which showed developmental stage-specific expression patterns. Finally, we showed that SCAN-seq exhibited high accuracy on determining allele-specific gene expression patterns within an individual cell. SCAN-seq makes a major breakthrough for single-cell transcriptome analysis field. This study describes a novel single-cell RNA-seq technology called SCAN-seq which can capture the full-length transcripts in single cells based on the third-generation Nanopore sequencing platform, and demonstrates its performance on mouse preimplantation embryos. [ABSTRACT FROM AUTHOR]

Published

2020

44. c-Src kinase inhibits osteogenic differentiation via enhancing STAT1 stability.

Author

Alvandi, Zahra and Opas, Michal

Subjects

*RUNX proteins, *NUCLEOCYTOPLASMIC interactions, *EMBRYONIC stem cells, *SMALL molecules, *CELL differentiation

Abstract

The proto-oncogene Src is ubiquitously expressed and is involved in cellular differentiation. However, the role of Src in embryonic stem (ES) cell osteogenic differentiation is largely unknown. Using the small molecule inhibitor PP2, c-Src specific siRNAs, and tet-inducible lentiviral vectors overexpressing active c-Src, we delineated an inhibitory role of c-Src in osteogenic differentiation of mouse embryonic stem cells (mESCs) and mouse MC3T3-E1s preosteoblasts. Active c-Src was shown to restrict the nuclear residency of Runt-related transcription factor 2 (Runx2) and its transcriptional activity with no detectable effect on Runx2 expression level. Furthermore, we showed Signal Transducer and Activator of Transcription 1 (STAT1) was indispensable to the inhibitory role of c-Src on Runx2 nuclear localization. Specifically, higher levels of active c-Src increased STAT1 half-life by inhibiting its proteasomal degradation, thereby increasing the cytoplasmic abundance of STAT1. More abundant cytoplasmic STAT1 bound and anchored Runx2, which restricted its nucleocytoplasmic shuttling and ultimately reduced Runx2 transcriptional activity. Collectively, this study has defined a new mechanism by which c-Src inhibits the transcriptional regulation of osteogenesis from mESCs in vitro. [ABSTRACT FROM AUTHOR]

Published

2020

45. Extensive trimming of short single-stranded DNA oligonucleotides during replication-coupled gene editing in mammalian cells.

Author

van Ravesteyn, Thomas W., Arranz Dols, Marcos, Pieters, Wietske, Dekker, Marleen, and te Riele, Hein

Subjects

*SINGLE-stranded DNA, *GENOME editing, *DNA replication, *DNA mismatch repair, *DNA repair, *EMBRYONIC stem cells, *OLIGONUCLEOTIDES

Abstract

Through transfection of short single-stranded oligodeoxyribonucleotides (ssODNs) small genomic alterations can be introduced into mammalian cells with high precision. ssODNs integrate into the genome during DNA replication, but the resulting heteroduplex is prone to detection by DNA mismatch repair (MMR), which prevents effective gene modification. We have previously demonstrated that the suppressive action of MMR can be avoided when the mismatching nucleotide in the ssODN is a locked nucleic acid (LNA). Here, we reveal that LNA-modified ssODNs (LMOs) are not integrated as intact entities in mammalian cells, but are severely truncated before and after target hybridization. We found that single additional (non-LNA-modified) mutations in the 5'-arm of LMOs influenced targeting efficiencies negatively and activated the MMR pathway. In contrast, additional mutations in the 3'-arm did not affect targeting efficiencies and were not subject to MMR. Even more strikingly, homology in the 3'-arm was largely dispensable for effective targeting, suggestive for extensive 3'-end trimming. We propose a refined model for LMO-directed gene modification in mammalian cells that includes LMO degradation. Author summary: The first step of many gene editing approaches in mammalian cells is to generate a targeted DNA lesion. By administering a repair template as second step, endogenous DNA repair mechanisms can be misled to introduce specific gene variants. However, subtle gene modification can also be achieved with high precision through a one-action protocol in the absence of DNA breaks. We have shown before that short single-stranded DNA molecules (LMOs) are very useful to introduce and study genetic variants that may predispose patients to cancer. While LMOs are known to integrate into the genome during DNA replication, the precise mechanism is poorly understood. We targeted mouse embryonic stem cells with differently designed LMOs to examine their effectiveness and editing outcomes. Based on these results we conclude that the two LMO termini are processed at different moments during the gene editing process. While the 3'-arm is degraded prior to LMO binding to the target site, the 5'-arm is degraded afterwards. Counterintuitively we also observe that partial degradation of the 3'-arm increases targeting efficiencies. Taken together our data provides novel mechanistic insight into our understanding of replication-coupled gene editing and may guide future LMO design strategies. [ABSTRACT FROM AUTHOR]

Published

2020

46. Nicotinamide restricts neural precursor proliferation to enhance catecholaminergic neuronal subtype differentiation from mouse embryonic stem cells.

Author

Griffin, Síle M., Pickard, Mark R., Hawkins, Clive P., Williams, Adrian C., and Fricker, Rosemary A.

Subjects

*NICOTINAMIDE, *NEURONAL differentiation, *STEM cell culture, *PLURIPOTENT stem cells, *PARKINSON'S disease, *EMBRYONIC stem cells, *VITAMINS

Abstract

Emerging evidence indicates that a strong relationship exists between brain regenerative therapies and nutrition. Early life nutrition plays an important role during embryonic brain development, and there are clear consequences to an imbalance in nutritional factors on both the production and survival of mature neuronal populations and the infant's risk of diseases in later life. Our research and that of others suggest that vitamins play a fundamental role in the formation of neurons and their survival. There is a growing body of evidence that nicotinamide, the water-soluble amide form of vitamin B3, is implicated in the conversion of pluripotent stem cells to clinically relevant cells for regenerative therapies. This study investigated the ability of nicotinamide to promote the development of mature catecholaminergic neuronal populations (associated with Parkinson's disease) from mouse embryonic stem cells, as well as investigating the underlying mechanisms of nicotinamide's action. Nicotinamide selectively enhanced the production of tyrosine hydroxylase-expressing neurons and serotonergic neurons from mouse embryonic stem cell cultures (Sox1GFP knock-in 46C cell line). A 5-Ethynyl-2´-deoxyuridine (EdU) assay ascertained that nicotinamide, when added in the initial phase, reduced cell proliferation. Nicotinamide drove tyrosine hydroxylase-expressing neuron differentiation as effectively as an established cocktail of signalling factors, reducing the proliferation of neural progenitors and accelerating neuronal maturation, neurite outgrowth and neurotransmitter expression. These novel findings show that nicotinamide enhanced and enriched catecholaminergic differentiation and inhibited cell proliferation by directing cell cycle arrest in mouse embryonic stem cell cultures, thus driving a critical neural proliferation-to-differentiation switch from neural progenitors to neurons. Further research into the role of vitamin metabolites in embryogenesis will significantly advance cell-based regenerative medicine, and help realize their role as crucial developmental signalling molecules in brain development. [ABSTRACT FROM AUTHOR]

Published

2020

47. A hypothetical trivalent epigenetic code that affects the nature of human ESCs.

Author

Ishikawa, Yasuhisa and Nakai, Kenta

Subjects

*DNA demethylation, *HUMAN behavior, *EPIGENOMICS, *EMBRYONIC stem cells, *GENE expression, *DNA methylation

Abstract

It has been suggested that DNA methylation can work in concert with other epigenetic factors, leading to changes in cellular phenotypes. For example, DNA demethylation modifications producing 5-hydroxymethylcytosine (5hmC) are thought to interact with histone modifications to influence the acquisition of embryonic stem cell (ESC) potency. However, the mechanism by which this occurs is still unknown. Thus, we systematically analysed the co-occurrence of DNA and histone modifications at genic regions as well as their relationship with ESC-specific expression using a number of heterogeneous public datasets. From a set of 19 epigenetic factors, we found remarkable co-occurrence of 5hmC and H4K8ac, accompanied by H3K4me1. This enrichment was more prominent at gene body regions. The results were confirmed using data obtained from different detection methods and species. Our analysis shows that these marks work cooperatively to influence ESC-specific gene expression. We also found that this trivalent mark is relatively enriched in genes related with immunity, which is a bit specific in ESCs. We propose that a trivalent epigenetic mark, composed of 5hmC, H4K8ac and H3K4me1, regulates gene expression and modulates the nature of human ESCs as a novel epigenetic code. [ABSTRACT FROM AUTHOR]

Published

2020

48. Polyploidy of semi-cloned embryos generated from parthenogenetic haploid embryonic stem cells.

Author

Aizawa, Eishi, Dumeau, Charles-Etienne, Freimann, Remo, Di Minin, Giulio, and Wutz, Anton

Subjects

*EMBRYONIC stem cells, *HAPLOIDY, *POLYPLOIDY, *EMBRYOS, *EMBRYOLOGY, *MAMMAL development

Abstract

In mammals, the fusion of two gametes, an oocyte and a spermatozoon, during fertilization forms a totipotent zygote. There has been no reported case of adult mammal development by natural parthenogenesis, in which embryos develop from unfertilized oocytes. The genome and epigenetic information of haploid gametes are crucial for mammalian development. Haploid embryonic stem cells (haESCs) can be established from uniparental blastocysts and possess only one set of chromosomes. Previous studies have shown that sperm or oocyte genome can be replaced by haESCs with or without manipulation of genomic imprinting for generation of mice. Recently, these remarkable semi-cloning methods have been applied for screening of key factors of mouse embryonic development. While haESCs have been applied as substitutes of gametic genomes, the fundamental mechanism how haESCs contribute to the genome of totipotent embryos is unclear. Here, we show the generation of fertile semi-cloned mice by injection of parthenogenetic haESCs (phaESCs) into oocytes after deletion of two differentially methylated regions (DMRs), the IG-DMR and H19-DMR. For characterizing the genome of semi-cloned embryos further, we establish ESC lines from semi-cloned blastocysts. We report that polyploid karyotypes are observed in semi-cloned ESCs (scESCs). Our results confirm that mitotically arrested phaESCs yield semi-cloned embryos and mice when the IG-DMR and H19-DMR are deleted. In addition, we highlight the occurrence of polyploidy that needs to be considered for further improving the development of semi-cloned embryos derived by haESC injection. [ABSTRACT FROM AUTHOR]

Published

2020

49. Evaluation of transplantation sites for human intestinal organoids.

Author

Singh, Akaljot, Poling, Holly M., Sundaram, Nambirajan, Brown, Nicole, Wells, James M., and Helmrath, Michael A.

Subjects

*EMBRYONIC stem cells, *CARBOHYDRATE metabolism, *MESSENGER RNA, *PROTEIN expression

Abstract

Our group has developed two transplantation models for the engraftment of Human Intestinal Organoids (HIOs): the renal subcapsular space (RSS) and the mesentery each with specific benefits for study. While engraftment at both sites generates laminated intestinal structures, a direct comparison between models has not yet been performed. Embryonic stem cells were differentiated into HIOs, as previously described. HIOs from the same batch were transplanted on the same day into either the RSS or mesentery. 10 weeks were allowed for engraftment and differentiation, at which time they were harvested and assessed. Metrics for comparison included: mortality, engraftment rate, gross size, number and grade of lumens, and expression of markers specific to epithelial differentiation, mesenchymal differentiation, and carbohydrate metabolism. Mortality was significantly increased when undergoing mesentery transplantation, however engraftment was significantly higher. Graft sizes were similar between groups. Morphometric parameters were similar between groups, however m-tHIOs presented with significantly fewer lumens than k-tHIO. Transcript and protein level expression of markers specific to epithelial differentiation, mesenchymal differentiation, and carbohydrate metabolism were similar between groups. Transplantation into both sites yields viable tissue of similar quality based on our assessments with enhanced engraftment and a dominant lumen for uniform study benefiting the mesenteric site and survival benefiting RSS. [ABSTRACT FROM AUTHOR]

Published

2020

50. Development of electrophysiological and morphological properties of human embryonic stem cell-derived GABAergic interneurons at different times after transplantation into the mouse hippocampus.

Author

Shrestha, Swechhya, Anderson, Nickesha C., Grabel, Laura B., Naegele, Janice R., and Aaron, Gloster B.

Subjects

*INTERNEURONS, *EMBRYONIC stem cells, *HUMAN embryonic stem cells, *ELECTROPHYSIOLOGY

Abstract

Transplantation of human embryonic stem cell (hESC)-derived neural progenitors is a potential treatment for neurological disorders, but relatively little is known about the time course for human neuron maturation after transplantation and the emergence of morphological and electrophysiological properties. To address this gap, we transplanted hESC-derived human GABAergic interneuron progenitors into the mouse hippocampus, and then characterized their electrophysiological properties and dendritic arborizations after transplantation by means of ex vivo whole-cell patch clamp recording, followed by biocytin staining, confocal imaging and neuron reconstruction software. We asked whether particular electrophysiological and morphological properties showed maturation-dependent changes after transplantation. We also investigated whether the emergence of particular electrophysiological properties were linked to increased complexity of the dendritic arbors. Human neurons were classified into five distinct neuronal types (Type I-V), ranging from immature to mature fast-spiking interneurons. Hierarchical clustering of the dendritic morphology and Sholl analyses suggested four morphologically distinct classes (Class A-D), ranging from simple/immature to highly complex. Incorporating all of our data regardless of neuronal classification, we investigated whether any electrophysiological and morphological features correlated with time post-transplantation. This analysis demonstrated that both dendritic arbors and electrophysiological properties matured after transplantation. [ABSTRACT FROM AUTHOR]

Published

2020