Durable pluripotency and haploidy in epiblast stem cells derived from haploid embryonic stem cells in vitro.

Haploid pluripotent stem cells, such as haploid embryonic stem cells (haESCs), facilitate the genetic study of recessive traits. In vitro, fish haESCs maintain haploidy in both undifferentiated and differentiated states, but whether mammalian haESCs can preserve pluripotency in the haploid state has not been tested. Here, we report that mouse haESCs can differentiate in vitro into haploid epiblast stem cells (haEpiSCs), which maintain an intact haploid genome, unlimited self-renewal potential, and durable pluripotency to differentiate into various tissues in vitro and in vivo. Mechanistically, the maintenance of self-renewal potential depends on the Activin/bFGF pathway. We further show that haEpiSCs can differentiate in vitro into haploid progenitor-like cells. When injected into the cytoplasm of an oocyte, androgenetic haEpiSC (ahaEpiSCs) can support embryonic development until midgestation (E12.5). Together, these results demonstrate durable pluripotency in mouse haESCs and haEpiSCs, as well as the valuable potential of using these haploid pluripotent stem cells in high-throughput genetic screening.

m(6)A RNA methylation is regulated by microRNAs and promotes reprogramming to pluripotency.

N(6)-methyladenosine (m(6)A) has been recently identified as a conserved epitranscriptomic modification of eukaryotic mRNAs, but its features, regulatory mechanisms, and functions in cell reprogramming are largely unknown. Here, we report m(6)A modification profiles in the mRNA transcriptomes of four cell types with different degrees of pluripotency. Comparative analysis reveals several features of m(6)A, especially gene- and cell-type-specific m(6)A mRNA modifications. We also show that microRNAs (miRNAs) regulate m(6)A modification via a sequence pairing mechanism. Manipulation of miRNA expression or sequences alters m(6)A modification levels through modulating the binding of METTL3 methyltransferase to mRNAs containing miRNA targeting sites. Increased m(6)A abundance promotes the reprogramming of mouse embryonic fibroblasts (MEFs) to pluripotent stem cells; conversely, reduced m(6)A levels impede reprogramming. Our results therefore uncover a role for miRNAs in regulating m(6)A formation of mRNAs and provide a foundation for future functional studies of m(6)A modification in cell reprogramming.

Lmx1a enhances the effect of iNSCs in a PD model.

Lmx1a plays a central role in the specification of dopaminergic (DA) neurons, which potentially could be employed as a key factor for trans-differentiation to DA neurons. In our previous study, we have converted somatic cells directly into neural stem cell-like cells, namely induced neural stem cells (iNSCs), which further can be differentiated into subtypes of neurons and glia in vitro. In the present study, we continued to test whether these iNSCs have therapeutic effects when transplanted into a mouse model of Parkinson's disease (PD), especially when Lmx1a was introduced into these iNSCs under a Nestin enhancer. iNSCs that over-expressed Lmx1a (iNSC-Lmx1a) gave rise to an increased yield of dopaminergic neurons and secreted a higher level of dopamine in vitro. When transplanted into mouse models of PD, both groups of mice showed decreased ipsilateral rotations; yet mice that received iNSC-Lmx1a vs. iNSC-GFP exhibited better recovery. Although few iNSCs survived 11weeks after transplantation, the improved motor performance in iNSC-Lmx1a group did correlate with a greater tyrosine hydroxylase (TH) signal abundance in the lesioned area of striatum, suggesting that iNSCs may have worked through a non-autonomous manner to enhance the functions of remaining endogenous dopaminergic neurons in brain.

Androgenetic haploid embryonic stem cells produce live transgenic mice.

Haploids and double haploids are important resources for studying recessive traits and have large impacts on crop breeding, but natural haploids are rare in animals. Mammalian haploids are restricted to germline cells and are occasionally found in tumours with massive chromosome loss. Recent success in establishing haploid embryonic stem (ES) cells in medaka fish and mice raised the possibility of using engineered mammalian haploid cells in genetic studies. However, the availability and functional characterization of mammalian haploid ES cells are still limited. Here we show that mouse androgenetic haploid ES (ahES) cell lines can be established by transferring sperm into an enucleated oocyte. The ahES cells maintain haploidy and stable growth over 30 passages, express pluripotent markers, possess the ability to differentiate into all three germ layers in vitro and in vivo, and contribute to germlines of chimaeras when injected into blastocysts. Although epigenetically distinct from sperm cells, the ahES cells can produce viable and fertile progenies after intracytoplasmic injection into mature oocytes. The oocyte-injection procedure can also produce viable transgenic mice from genetically engineered ahES cells. Our findings show the developmental pluripotency of androgenentic haploids and provide a new tool to quickly produce genetic models for recessive traits. They may also shed new light on assisted reproduction.

Generation of tripotent neural progenitor cells from rat embryonic stem cells.

Rat is a valuable model for pharmacological and physiological studies. Germline-competent rat embryonic stem (rES) cell lines have been successfully established and the molecular networks maintaining the self-renewing, undifferentiated state of rES cells have also been well uncovered. However, little is known about the differentiation strategies and the underlying mechanisms of how these authentic rat pluripotent stem cells give rise to specific cell types. The aim of this study is to investigate the neural differentiation capacity of rES cells. By means of a modified procedure based on previous publications - combination of mitogen-activated protein kinase (MAPK) and glycogen synthase kinase 3 (GSK3) inhibitors (two inhibitors, "2i") with feeder-conditioned medium, we successfully obtained high-quality rat embryoid bodies (rEBs) from rES cells and then differentiated them to tripotent neural progenitors. These rES cell-derived neural progenitor cells (rNPCs) were capable of self-renewing and giving rise to all three neural lineages, including astrocytes, oligodendrocytes, and neurons. Besides, these rES cell-derived neurons stained positive for γ-aminobutyric acid (GABA) and tyrosine hydroxylase (TH). In summary, we develop an experimental system for differentiating rES cells to tripotent neural progenitors, which may provide a powerful tool for pharmacological test and a valuable platform for studying the pathogenesis of many neurodegenerative disorders such as Parkinson's disease and the development of rat nervous system.