The risk of tumorigenicity is a hurdle for regenerative medicine using induced pluripotent stem cells (iPSCs). Although teratoma formation is readily distinguishable, the malignant transformation of iPSC derivatives has not been clearly defined due to insufficient analysis of histology and phenotype. In the present study, we evaluated the histology of neural stem/progenitor cells (NSPCs) generated from integration-free human peripheral blood mononuclear cell (PBMC)-derived iPSCs (iPSC-NSPCs) following transplantation into central nervous system (CNS) of immunodeficient mice. We found that transplanted iPSC-NSPCs produced differentiation patterns resembling those in embryonic CNS development, and that the microenvironment of the final site of migration affected their maturational stage. Genomic instability of iPSCs correlated with increased proliferation of transplants, although no carcinogenesis was evident. The histological classifications presented here may provide cues for addressing potential safety issues confronting regenerative medicine involving iPSCs.Electronic supplementary materialThe online version of this article (doi:10.1186/s13041-016-0265-8) contains supplementary material, which is available to authorized users.
Human neural progenitor cells (hNPCs) have previously been generated from limited numbers of human induced pluripotent stem cell (hiPSC) clones. Here, 21 hiPSC clones derived from human dermal fibroblasts, cord blood cells, and peripheral blood mononuclear cells were differentiated using two neural induction methods, an embryoid body (EB) formation-based method and an EB formation method using dual SMAD inhibitors (dSMADi). Our results showed that expandable hNPCs could be generated from hiPSC clones with diverse somatic tissue origins. The established hNPCs exhibited a mid/hindbrain-type neural identity and uniform expression of neural progenitor genes.
In vitro, human neural stem cells can be selectively expanded from fetal or adult neural tissues as neurospheres consisting of immature neural progenitor cells. Access to human neural tissues is limited, making it difficult to propagate and use primary neural stem or progenitor cells (NSPCs) from human neural tissues (hN-NSPCs). It was recently demonstrated that hN-NSPCs can be differentiated from either human embryonic stem cells (hESC-NSPCs) or human-induced pluripotent stem cells (hiPSC-NSPCs), and that hESC-NSPCs and hiPSC-NSPCs are adaptable, powerful substitutes for hN-NSPCs in both regenerative medicine and pharmacological or neurotoxicological assays. We here describe a new protocol to generate neurospheres consisting of hiPSC-NSPCs using microsphere arrays, the surface of which is modified with polyethylene glycol to render it nonadhesive to cells. Primary hiPSCs treated with noggin formed neurospheres on the microsphere arrays and could be stably propagated as free-floating spheroids. The hiPSC-NSPCs proliferating in these neurospheres were almost identical in phenotype to hN-NSPCs, in both cell-surface marker expression and their ability to differentiate into neuronal cells, although gene expression profiles showed that the hiPSC-NSPCs had higher neural and lower glial gene expression, along with mid-hindbrain-like regional specificity. This convenient propagation protocol can be used to evaluate the neurosphere-forming efficiency of hiPSC clones. This method will support the generation of neurospheres from hESCs and hiPSCs and contribute to the use of hESC-NSPCs and hiPSC-NSPCs in research.
Human ES cells (hESCs) and human induced pluripotent stem cells (hiPSCs) are usually generated and maintained on living feeder cells like mouse embryonic fibroblasts or on a cell-free substrate like Matrigel. For clinical applications, a quality-controlled, xenobiotic-free culture system is required to minimize risks from contaminating animal-derived pathogens and immunogens. We previously reported that the pericellular matrix of decidua-derived mesenchymal cells (PCM-DM) is an ideal human-derived substrate on which to maintain hiPSCs/hESCs. In this study, we examined whether PCM-DM could be used for the generation and long-term stable maintenance of hiPSCs. Decidua-derived mesenchymal cells (DMCs) were reprogrammed by the retroviral transduction of four factors (OCT4, SOX2, KLF4, c-MYC) and cultured on PCM-DM. The established hiPSC clones expressed alkaline phosphatase, hESC-specific genes and cell-surface markers, and differentiated into three germ layers in vitro and in vivo. At over 20 passages, the hiPSCs cultured on PCM-DM held the same cellular properties with genome integrity as those at early passages. Global gene expression analysis showed that the GDF3, FGF4, UTF1, and XIST expression levels varied during culture, and GATA6 was highly expressed under our culture conditions; however, these gene expressions did not affect the cells’ pluripotency. PCM-DM can be conveniently prepared from DMCs, which have a high proliferative potential. Our findings indicate that PCM-DM is a versatile and practical human-derived substrate that can be used for the feeder-cell-free generation and long-term stable maintenance of hiPSCs.
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