Peripheral sensory neurons differentiate from neural precursors derived from human embryonic stem cells

Abstract Neural precursors have been derived from human embryonic stem cells (hESC) using the bone morphogenetic protein antagonist noggin. These neural precursors can be further differentiated to produce neural cells that express central nervous system (CNS) markers. We have recently shown that naïve hESC can be directed to differentiate into peripheral sensory (PS) neuron-like cells and putative neural crest precursors by co-culturing with PA6 stromal cells. In the present study, we examine whether hESC-derived neural precursors (NPC) can differentiate into the peripheral nervous system, as well as CNS cells. As little as 1 week after co-culture with PA6 cells, cells with the molecular characteristics of PS neurons and neural crest are observed in the cultures. With increased time in culture, more PS-like neurons appear, in parallel with a reduction in the neural crest-like cells. These results provide the first evidence that neural precursors derived from hESC have the potential to develop into PS neurons-like as well as CNS-like neuronal cells. About 10% of the cells in NPC-PA6 co-cultures express PS neuron markers after 3 weeks, compared with <1% of hESC cultured on PA6. This enrichment for peripheral neurons makes this an attractive system for generation of peripheral neurons for pathophysiology study and drug development for diseases of the peripheral nervous system such as Familial Dysautonomia and varicella virus infection.     

Neural precursors derived from human embryonic stem cells

Human embryonic stem (hES) cells provide a promising supply of specific cell types for transplantation therapy. We presented here the method to induce differentiation of purified neural precursors from hES cells. hES cells (Line PKU-1 and Line PKU-2) were cultured in suspension in bacteriological Petri dishes, which differentiated into cystic embryoid bodies (EBs). The EBs were then cultured in N₂ medium containing bFGF in poly-L-lysine-coated tissue culture dishes for two weeks. The central, small cells with 2–3 short processes of the spreading outgrowth were isolated mechanically and replated. The resulting neurospheres were cultured in suspension for 10 days, then dissociated into single cell suspension with a Pasteur pipette and plated. Cells grew vigorously in an attached way and were passed every 4–5 days. Almost all the cells were proved nestin positive by immunostaining. Following withdrawal of bFGF, they differentiated into neurons expressing β-tubulin isotype_III, GABA, serotonin and synaptophysin. Through induction of PDGF-AA, they differentiated into astrocytes expressing GFAP and oligodendrocytes expressing O₄. The results showed that hES cells can differentiate into typical neural precursors expressing the specific marker nestin and capable of generating all three cell types of the central nervous system (CNS)in vitro.     

Neural precursors derived from human embryonic stem cells

Before the successful isolation of human embryonic stem (hES) cells, many investigations had shown that mouse embryonic stem (mES) cells can be induced to differentiate into neural precursors which could be purified and differentiated to mature dopamine, motor, serotonin, GABA neurons, and oligodendrocytes and astrocytes in vitro[1―3]. mES cell-derived dopamine neurons have been shown capable of integrating into host brains after transplanting to the rodents of Park-inson’s disease model …     

Neural precursors derived from human embryonic stem cells maintain long-term proliferation without losing the potential to differentiate into all three neural lineages, including dopaminergic neurons

Human embryonic stem (hES) cells have the ability to renew themselves and differentiate into multiple cell types upon exposure to appropriate signals. In particular, the ability of hES cells to differentiate into defined neural lineages, such as neurons, astrocytes, and oligodendrocytes, is fundamental to developing cell-based therapies for neurodegenerative disorders and studying developmental mechanisms. However, the utilization of hES cells for basic and applied research is hampered by the lack of well-defined methods to maintain their self-renewal and direct their differentiation. Recently we reported that neural precursor (NP) cells derived from mouse ES cells maintained their potential to differentiate into dopaminergic (DA) neurons after significant expansion in vitro . We hypothesized that NP cells derived from hES cells (hES-NP) could also undergo the same in vitro expansion and differentiation. To test this hypothesis, we passaged hES-NP cells and analyzed their proliferative and developmental properties. We found that hES-NP cells can proliferate approximately 380 000-fold after in vitro expansion for 12 weeks and maintain their potential to generate Tuj1⁺ neurons, GFAP⁺ astrocytes, and O4⁺ oligodendrocytes as well as tyrosine hydroxylase-positive (TH⁺) DA neurons. Furthermore, TH⁺ neurons originating from hES-NP cells expressed other midbrain DA markers, including Nurr1, Pitx3, Engrail-1, and aromatic l -amino acid decarboxylase, and released significant amounts of DA. In addition, hES-NP cells maintained their developmental potential through long-term storage (over 2 years) in liquid nitrogen and multiple freeze–thaw cycles. These results demonstrate that hES-NP cells have the ability to provide an expandable and unlimited human cell source that can develop into specific neuronal and glial subtypes.     

Embryonic stem cell-derived neural progenitors as non-tumorigenic source for dopaminergic neurons

AIM:To find a safe source for dopaminergic neurons,we generated neural progenitor cell lines from human embryonic stem cells.METHODS:The human embryonic stem(hES)cell line H9 was used to generate human neural progenitor(HNP)cell lines.The resulting HNP cell lines were differentiated into dopaminergic neurons and analyzed by quantitative real-time polymerase chain reaction and immunofluorescence for the expression of neuronal differentiation markers,including beta-III tubulin(TUJ1)and tyrosine hydroxylase(TH).To assess the risk of teratoma or other tumor formation,HNP cell lines and mouse neuronal progenitor(MNP)cell lines were injected subcutaneously into immunodeficient SCID/beige mice.RESULTS:We developed a fairly simple and fast protocol to obtain HNP cell lines from hES cells.These cell lines,which can be stored in liquid nitrogen for several years,have the potential to differentiate in vitro into dopaminergic neurons.Following day 30 of differentiation culture,the majority of the cells analyzed expressed the neuronal marker TUJ1 and a high proportion of these cells were positive for TH,indicating differentiation into dopaminergic neurons.In contrast to H9 ES cells,the HNP cell lines did not form tumors in immunodeficient SCID/beige mice within 6 mo after subcutaneous injection.Similarly,no tumors developed after injection of MNP cells.Notably,mouse ES cells or neuronal cells directly differentiated from mouse ES cells formed teratomas in more than 90%of the recipients.CONCLUSION:Our findings indicate that neural progenitor cell lines can differentiate into dopaminergic neurons and bear no risk of generating teratomas or other tumors in immunodeficient mice.     

Human neural progenitor cells derived from embryonic stem cells in feeder-free cultures

Derivation of human neural progenitors (hNP) from human embryonic stem (hES) cells in culture has been reported with the use of feeder cells or conditioned media. This introduces undefined components into the system, limiting the ability to precisely investigate the requirement for factors that control the process. Also, the use of feeder cells of non-human origin introduces the potential for zoonotic transmission, limiting its clinical usefulness. Here we report a feeder-free system to produce hNP from hES cells and test the effects of various media components involved in the process. Five protocols using defined media components were compared for efficiency of hNP generation. Based on this analysis, we discuss the role of basic fibroblast growth factor (FGF2), N2 supplement, non-essential amino acids (NEAA), and knock-out serum replacement (KSR) on the process of hNP generation. All protocols led to down-regulation of Oct4/POU5F1 expression (from 90.5% to <3%), and up-regulation of neural progenitor markers to varying degrees. Media with N2 but not KSR and NEAA produced cultures with significantly higher (p<0.05) expression of the neural progenitor marker Musashi 1 (MSI1). Approximately 89% of these cells were Nestin (NES)+ after 3 weeks, but they did not proliferate. In contrast, differentiation media supplemented with KSR and NEAA produced fewer NES+ (75%) cells, but these cells were proliferative, and by five passages the culture consisted of >97% NES+ cells. This suggests that KSR and NEAA supplements did not enhance early differentiation but did promote proliferating of hNP cell cultures. This resulted in an efficient, robust, repeatable differentiation system suitable for generating large populations of hNP cells. This will facilitate further study of molecular and biochemical mechanisms in early human neural differentiation and potentially produce uniform neuronal cells for therapeutic uses without concern of zoonotic transmission from feeder layers.     

Murine embryonic stem cells as a model for human embryonic stem-cell research

Over the last several decades, murine embryonic stem cells (mESCs) have been used as a model for human embryonic stem cell (hESC) research. The relevance of this approach has not yet been proven. There is a great deal of evidence that is indicative of substantial differences between these two cell types. An analysis of the literature shows that the differences concern ESC proliferation, self-renewal, and differentiation. Consequently, mESC may be considered as a model object for hESC studies only for some aspects of their biology. The alternative model objects, such as primate ESC, are also discussed briefly in this review.     

An adherent-cell depletion technique to generate human neural progenitors and neurons

Existing methodologies to produce human neural stem cells and neurons from embryonic stem cells frequently involve multistep processes and the use of complex and expensive media components, cytokines or small molecules. Here, we report a simple technique to generate human neuroepithelial progenitors and neurons by periodic mechanical dissection and adherent-cell depletion on regular cell-culture grade plastic surfaces. This neural induction technique does not employ growth factors, small molecules or peptide inhibitors, apart from those present in serum-free supplements. Suggestive of their central nervous system origin, we found that neural progenitors formed by this technique expressed radial glia markers, and, when differentiated, expressed TUBB3, RBFOX3 (NeuN) and serotonin, but not markers for peripheral neurons. With these data, we postulate that incorporation of periodic mechanical stimuli and plastic surface-mediated cell selection could improve and streamline existing human neuron production protocols.     

Neural differentiation of human embryonic stem cells

Availability of human embryonic stem cells (hESC) has enhanced human neural differentiation research. The derivation of neural progenitor (NP) cells from hESC facilitates the interrogation of human embryonic development through the generation of neuronal subtypes and supporting glial cells. These cells will likely lead to novel drug screening and cell therapy uses. This review will discuss the current status of derivation, maintenance and further differentiation of NP cells with special emphasis on the cellular signaling involved in these processes. The derivation process affects the yield and homogeneity of the NP cells. Then when exposed to the correct environmental signaling cues, NP cells can follow a unique and robust temporal cell differentiation process forming numerous phenotypes.     

Genetic approach to track neural cell fate decisions using human embryonic stem cells

With their capability to undergo unlimited self-renewal and to differentiate into all cell types in the body, human embryonic stem cells (hESCs) hold great promise in human cell therapy. However, there are limited tools for easily identifying and isolating live hESC-derived cells. To track hESC-derived neural progenitor cells (NPCs), we applied homologous recombination to knock-in the mCherry gene into the Nestin locus of hESCs. This facilitated the genetic labeling of Nestin positive neural progenitor cells with mCherry. Our reporter system enables the visualization of neural induction from hESCs both in vitro (embryoid bodies) and in vivo (teratomas). This system also permits the identification of different neural subpopulations based on the intensity of our fluorescent reporter. In this context, a high level of mCherry expression showed enrichment for neural progenitors, while lower mCherry corresponded with more committed neural states. Combination of mCherry high expression with cell surface antigen staining enabled further enrichment of hESC-derived NPCs. These mCherry⁺NPCs could be expanded in culture and their differentiation resulted in a down-regulation of mCherry consistent with the loss of Nestin expression. Therefore, we have developed a fluorescent reporter system that can be used to trace neural differentiation events of hESCs.     

Human embryonic stem cells: Problems and perspectives

Generation of human embryonic stem cell lines is one of the most important achievements in biological science in the 20th century. It has excited a wide scientific and social response, as embryonic stem cells (ESC) may, in the future, be regarded as an unlimited source of transplantation materials for replacement cell therapy. ESC lines are derived, cultured, inner cell mass from human blastocysts is used in the in vitro fertilization procedure. To date, human embryonic cell lines have been obtained in more than 20 countries. In our country, embryonic stem cell research is carried out in the Institute of Cytology, Russian Academy of Sciences and the Institute of Gene Biology, Russian Academy of Sciences. Studies with human ESC go in several directions. Much attention is paid to finding the most optimal conditions for ESC cultivation, mainly to the development of cultivation techniques excluding animal feeder cells and other components of animal origin. Another direction is a large-scale analysis of gene expression specific to the embryonic state of cells and the corresponding signaling pathways. Great efforts are being focused on the directed differentiation of ESC into various tissue-specific cells. It has been shown that in vitro ESC are able to differentiate into virtually any somatic cells. Works are in progress to develop methods for “therapeutic cloning,” i.e. the transfer of somatic nuclei into enucleated oocytes or embryonic stem cell cytoblasts and their reactivation. Of great importance is the standardization of the human ESC lines. However, standard requirements for cells utilized for research or therapeutic purposes may be different. It has been found that many permanent human ESC lines underwent genetic and epigenetic variations. Therefore, the cell line genetic stability should be periodically verified. The main purpose of the review is to provide a detailed consideration of research on the genetic stability of human and mouse ESC lines. Human ESC lines established both in our country and others could not thus far be used in clinical practice. It is highly probable that undifferentiated ESCs cannot be applied for therapeutic purposes, as there is a risk of their malignant transformation. Therefore, main efforts should be focused on the production ESC progenitor and highly differentiated cells suitable for transplantation.     

Requirements for human embryonic stem cells

‘Requirements for Human Embryonic Stem Cells’ is the first set of guidelines on human embryonic stem cells in China, jointly drafted and agreed upon by experts from the Chinese Society for Stem Cell Research. This standard specifies the technical requirements, test methods, test regulations, instructions for use, labelling requirements, packaging requirements, storage requirements and transportation requirements for human embryonic stem cells, which is applicable to the quality control for human embryonic stem cells. It was originally released by the China Society for Cell Biology on 26 February 2019 and was further revised on 30 April 2020. We hope that publication of these guidelines will promote institutional establishment, acceptance and execution of proper protocols, and accelerate the international standardization of human embryonic stem cells for applications.     

Improved development of human embryonic stem cell-derived embryoid bodies by stirred vessel cultivation

Human embryonic stem cells (hESCs) represent an important resource for novel cell-based regenerative medical therapies. hESCs are known to differentiate into mature cells of defined lineages through the formation of embryoid bodies (EBs) which are amenable to suspension culture for several weeks. However, EBs derived from hESCs in standard static cultures are typically non-homogeneous, leading to inefficient cellular development. Here, we systematically compare the formation, growth, and differentiation capabilities of hESC-derived EBs in stirred and static suspension cultures. A 15-fold expansion in total number of EB-derived cells cultured for 21 days in a stirred flask was observed, compared to a fourfold expansion in static (non-stirred) cultures. Additionally, stirred vessel mediated cultures have a more homogeneous EB morphology and size. Importantly, the EBs cultivated in spinner flasks retained comparable ability to produce hematopoietic progenitor cells as those grown in static culture. These results demonstrate the decoupling between EB cultivation method and EB-derived cells' ability to form hematopoietic progenitors, and will allow for improved production of scalable quantities of hematopoietic cells or other differentiated cell lineages from hESCs in a controlled environment.     

The embryonic midbrain directs neuronal specification of embryonic stem cells at early stages of differentiation

Specific neuronal differentiation of Embryonic Stem Cells (ESCs) depends on their capacity to interpret environmental cues. At present, it is not clear at which stage of differentiation ESCs become competent to produce multiple neuronal lineages in response to the niche of the embryonic brain. To unfold the developmental potential of ESC-derived precursors, we transplanted these cells into the embryonic midbrain explants, where neurogenesis occurs as in normal midbrain development. Using this experimental design, we show that the transition from ESCs to Embryoid Body (EB) precursors is necessary to differentiate into Lmx1a⁺/Ptx3⁺/TH⁺ dopaminergic neurons around the ventral midline of the midbrain. In addition, EB cells placed at other dorsal-ventral levels of the midbrain give rise to Nkx6.1⁺ red nucleus (RN) neurons, Nkx2.2⁺ ventral interneurons and Pax7⁺ dorsal neurons at the correct positions. Notably, differentiation of ESCs into Neural Precursor Cells (NPCs) prior to transplantation markedly reduces specification at the Lmx1a, Nkx6.1 and Pax7 expression domains, without affecting neuronal differentiation. Finally, exposure to Fgf8 and Shh in vitro promotes commitment of some ESC-derived NPCs to differentiate into putative Lmx1a⁺ dopaminergic neurons in the midbrain. Our data demonstrate intrinsic developmental potential differences among ESC-derived precursor populations.     

Bioluminescence reporter gene imaging characterize human embryonic stem cell-derived teratoma formation

Human embryonic stem (hES) cells have a potential use for the repair and regeneration of injured tissues. However, teratoma formation can be a major obstacle for hES-mediated cell therapy. Therefore, tracking the fate and function of transplanted hES cells with noninvasive imaging could be valuable for a better understanding of the biology and physiology of teratoma formation. In this study, hES cells were stably transduced with a double fusion reporter gene consisting of firefly luciferase and enhanced green fluorescent protein. Following bioluminescence imaging and histology, we demonstrated that engraftment of hES cells was followed by dramatically increasing signaling and led to teratoma formation confirmed by histology. Studies of the angiogenic processes within teratomas revealed that their vasculatures were derived from both differentiated hES cells and host. Moreover, FACS analysis showed that teratoma cells derived from hES cells expressed high levels of CD56 and SSEA-4, and the subcultured SSEA-4(+) cells showed a similar cell surface marker expression pattern when compared to undifferentiated hES cells. We report here for the first time that SSEA-4(+) cells derived from teratoma exhibited multipotency, retained their differentiation ability in vivo as confirmed by their differentiation into representative three germ layers.