Takumi Era

Induction and monitoring of definitive and visceral endoderm differentiation of mouse ES cells

Preparation of specific lineages at high purities from embryonic stem (ES) cells requires both selective culture conditions and markers to guide and monitor the differentiation. In this study, we distinguished definitive and visceral endoderm by using a mouse ES cell line that bears the gfp and human IL2Rα (also known as CD25) marker genes in the goosecoid (Gsc) and Sox17 loci, respectively. This cell line allowed us to monitor the generation of Gsc+Sox17+ definitive endoderm and Gsc−Sox17+ visceral endoderm and to define culture conditions that differentially induce definitive and visceral endoderm. By comparing the gene expression profiles of definitive and visceral endoderm, we identified seven surface molecules that are expressed differentially in the two populations. One of the seven markers, Cxcr4, to which a monoclonal antibody is available allowed us to monitor and purify the Gsc+ population from genetically unmanipulated ES cells under the condition that selects definitive endoderm.

In utero manipulation of coat color formation by a monoclonal anti-c-kit antibody: Two distinct waves of c-kit-dependency during melanocyte development

Previous studies on mice bearing various mutations within the c‐kit gene, dominant white spotting (W), indicate the functional role of this tyrosine kinase receptor in the development of melanocytes, germ cells and hematopoietic cells. Despite the availability of mice defective in the c‐kit gene and a respectable understanding of the molecular nature of c‐kit, however, it is not clear at what stage of gestation c‐kit is functionally required for the development of each of these cell lineages. To address this question, we have used a monoclonal anti‐c‐kit antibody, ACK2, as an antagonistic blocker of c‐kit function to interfere with the development of melanocytes during embryonic and postnatal life. ACK2 injected intradermally into pregnant mice entered the embryos where it blocked the proper development of melanocytes. This inhibitory effect was manifested as coat color alteration in the offspring. Furthermore, ACK2 injection also altered the coat color of neonatal and adult mice. Based on the coat color patterns produced by ACK2 administration at various stages before or after birth, the following conclusions are drawn: (i) during mid‐gestation, c‐kit is functionally required during a restricted period around day 14.5 post‐coitum when a sequence of events leading to melanocyte entry into the epidermal layer occurs; (ii) during postnatal life, c‐kit is required for melanocyte activation which occurs concomitantly with the hair cycle which continues throughout life after neonatal development of the first hair.

Characterization of mesendoderm: a diverging point of the definitive endoderm and mesoderm in embryonic stem cell differentiation culture

Bipotent mesendoderm that can give rise to both endoderm and mesoderm is an established entity from C. elegans to zebrafish. Although previous studies in mouse embryo indicated the presence of bi-potent mesendoderm cells in the organizer region, characterization of mesendoderm and its differentiation processes are still unclear. As bi-potent mesendoderm is implicated as the major precursor of definitive endoderm, its identification is also essential for exploring the differentiation of definitive endoderm. In this study, we have established embryonic stem (ES) cell lines that carry GFP gene in the goosecoid (Gsc) gene locus and have investigated the differentiation course of mesendodermal cells using Gsc expression as a marker. Our results show that mesendoderm is represented as a Gsc-GFP+E-cadherin(ECD)+PDGFRα(αR)+ population and is selectively induced from ES cells under defined conditions containing either activin or nodal. Subsequently, it diverges to Gsc+ECD+αR- and Gsc+ECD-αR+ intermediates that eventually differentiate into definitive endoderm and mesodermal lineages, respectively. The presence of mesendodermal cells in nascent Gsc+ECD+αR+ population was also confirmed by single cell analysis. Finally, we show that the defined culture condition and surface markers developed in this study are applicable for obtaining pure mesendodermal cells and their immediate progenies from genetically unmanipulated ES cells.

Neuroepithelial Cells Supply an Initial Transient Wave of MSC Differentiation

Mesenchymal stem cells (MSCs) are defined as cells that undergo sustained in vitro growth and are able to give rise to multiple mesenchymal lineages. Although MSCs are already used in regenerative medicine little is known about their in vivo behavior and developmental derivation. Here, we show that the earliest wave of MSC in the embryonic trunk is generated from Sox1+ neuroepithelium but not from mesoderm. Using lineage marking by direct gfp knock-in and Cre-recombinase mediated lineage tracing, we provide evidence that Sox1+ neuroepithelium gives rise to MSCs in part through a neural crest intermediate stage. This pathway can be distinguished from the pathway through which Sox1+ cells give rise to oligodendrocytes by expression of PDGFRbeta and A2B5. MSC recruitment from this pathway, however, is transient and is replaced by MSCs from unknown sources. We conclude that MSC can be defined as a definite in vivo entity recruited from multiple developmental origins.

The T-box transcription factor Eomes/Tbr2 regulates neurogenesis in the cortical subventricular zone

The embryonic subventricular zone (SVZ) is a critical site for generating cortical projection neurons; however, molecular mechanisms regulating neurogenesis specifically in the SVZ are largely unknown. The transcription factor Eomes/Tbr2 is transiently expressed in cortical SVZ progenitor cells. Here we demonstrate that conditional inactivation of Tbr2 during early brain development causes microcephaly and severe behavioral deficits. In Tbr2 mutants the number of SVZ progenitor cells is reduced and the differentiation of upper cortical layer neurons is disturbed. Neurogenesis in the adult dentate gyrus but not the subependymal zone is abolished. These studies establish Tbr2 as a key regulator of neurogenesis in the SVZ.

In vitro modeling of paraxial and lateral mesoderm differentiation reveals early reversibility

Endothelial cells (ECs) are thought to be derived mainly from the vascular endothelial growth factor receptor 2 (VEGFR‐2)+ lateral mesoderm during early embryogenesis. In this study, we specified several pathways for EC differentiation using a murine embryonic stem (ES) cell differentiation culture system that is a model for cellular processes during early embryogenesis. Based on the results of in vitro fate analysis, we show that, in the main pathway, committed ECs are differentiated through the VEGFR‐2+ platelet‐derived growth factor receptor α (PDGFR‐α)− single‐positive (VSP) population that is derived from the VEGFR‐2+PDGFR‐α+ double‐positive (DP) population. This major differentiation course was also confirmed using DNA microarray analysis. In addition to this main pathway, however, ECs also can be generated from the VEGFR‐2−PDGFR‐α+ single‐positive (PSP) population, which represents the paraxial mesodermal lineage and is also derived from the DP population. Our results strongly suggest that, even after differentiation from the common progenitor DP population into the VSP and PSP populations, these two populations continue spontaneous switching of their surface phenotype, which results in switching of their eventual fates. The rate of this interlineage conversion between VSP and PSP is unexpectedly high. Because of this potential to undergo fate switch, we conclude that ECs can be generated via multiple pathways in in vitro ES cell differentiation.

Embryonic stem-cell culture as a tool for developmental cell biology

The cell biology of the early processes of mammalian embryogenesis, such as germ-layer formation, has been technically challenging to study owing to the size and accessibility of mammalian embryos. Embryonic stem cells, which can generate the three germ layers in vitro, are useful for studying embryogenesis at the cellular level. So, how can the study of embryonic stem cells and their differentiation provide a deeper understanding of the cell biology of early development?

Efficient and Reproducible Myogenic Differentiation from Human iPS Cells: Prospects for Modeling Miyoshi Myopathy In Vitro

The establishment of human induced pluripotent stem cells (hiPSCs) has enabled the production of in vitro, patient-specific cell models of human disease. In vitro recreation of disease pathology from patient-derived hiPSCs depends on efficient differentiation protocols producing relevant adult cell types. However, myogenic differentiation of hiPSCs has faced obstacles, namely, low efficiency and/or poor reproducibility. Here, we report the rapid, efficient, and reproducible differentiation of hiPSCs into mature myocytes. We demonstrated that inducible expression of myogenic differentiation1 (MYOD1) in immature hiPSCs for at least 5 days drives cells along the myogenic lineage, with efficiencies reaching 70–90%. Myogenic differentiation driven by MYOD1 occurred even in immature, almost completely undifferentiated hiPSCs, without mesodermal transition. Myocytes induced in this manner reach maturity within 2 weeks of differentiation as assessed by marker gene expression and functional properties, including in vitro and in vivo cell fusion and twitching in response to electrical stimulation. Miyoshi Myopathy (MM) is a congenital distal myopathy caused by defective muscle membrane repair due to mutations in DYSFERLIN. Using our induced differentiation technique, we successfully recreated the pathological condition of MM in vitro, demonstrating defective membrane repair in hiPSC-derived myotubes from an MM patient and phenotypic rescue by expression of full-length DYSFERLIN (DYSF). These findings not only facilitate the pathological investigation of MM, but could potentially be applied in modeling of other human muscular diseases by using patient-derived hiPSCs.

GATA-2 and GATA-2/ER display opposing activities in the development and differentiation of blood progenitors

GATA‐2 is a zinc finger transcription factor essential for the development of hematopoiesis. While GATA‐2 is generally considered to play an important role in the biology of hematopoietic stem and progenitor cells, its function within these compartments is not well understood. Here we have employed both conditional expression of GATA‐2 and conditional activation of a GATA‐2/estrogen receptor (ER) chimera to examine the effect of enforced GATA‐2 expression in the development and differentiation of hematopoietic progenitors from murine embryonic stem cells. Consistent with the phenotype of GATA‐2 null animals, conditional expression of GATA‐2 from a tetracycline‐inducible promoter enhanced the production of hematopoietic progenitors. Conditional activation of a GATA‐2/ER chimera produced essentially opposite effects to those observed with conditional GATA‐2 expression. GATA‐2 and GATA‐2/ER differ in their binding activities and transcriptional interactions from other hematopoietic‐associated transcription factors such as c‐Myb and PU.1. While we have exploited these differences in activity to explore the transcriptional networks underlying hematopoietic cell fate determination, our results suggest that care should be taken in interpreting results obtained using only chimeric proteins.

Differentiation of growth signal requirement of B lymphocyte precursor is directed by expression of immunoglobulin

During B cell differentiation, at least three stages can be defined in terms of their growth signal requirement by using two different growth signals, which are recombinant interleukin 7 (IL‐7) and a stromal cell clone PA6 which does not produce IL‐7; first a PA6 dependent stage, second a PA6 + IL‐7 dependent stage and third an IL‐7 dependent stage. In order to test the possibility that this differentiation of growth signal requirement is controlled by the expression of functional immunoglobulin molecules, we have investigated the frequencies of PA6 + IL‐7 dependent and IL‐7 dependent cells which are present in the bone marrow of either mu‐chain or kappa‐chain gene transgenic mice. In a mu‐chain gene transgenic mouse, the frequency of PA6 + IL‐7 dependent cells is selectively reduced, while that of IL‐7 dependent cells is selectively reduced in a kappa‐chain gene transgenic mouse. This result suggests that expression of a functional mu‐chain gene drives PA6 + IL‐7 dependent cells to differentiate into the subsequent IL‐7 dependent stage. Likewise, when mu‐chain positive IL‐7 dependent cells express a functional light‐chain gene, their growth signal requirement changes into an IL‐7 unreactive stage.