A culture medium is disclosed which comprises STAT3 activator, an ERK1/2 inhibitor and an Axin stabilizer, and optionally also a PKC inhibitor. Cell cultures comprising same and uses thereof are also disclosed.

An object is to prepare an intestinal organoid having a characteristic close to the small intestine of a living body, from a pluripotent stem cell. An intestinal organoid is prepared from a pluripotent stem cell, by the following steps of: (1) differentiating the pluripotent stem cell into an endoderm-like cell; (2) differentiating the endoderm-like cell obtained in step (1) into an intestinal stem cell-like cell; (3) culturing the intestinal stem cell-like cell obtained in step (2) in the presence of an epidermal growth factor, a fibroblast growth factor, a TGF β receptor inhibitor, a GSK-3 β inhibitor, and a ROCK inhibitor; (4) culturing the cell obtained in step (3) to form a spheroid; and (5) differentiating the spheroid formed in step (4) to form an intestinal organoid, wherein the differentiation includes culturing in the presence of an epidermal growth factor, a BMP inhibitor, and a Wnt signal activator. Also, a plane culture system is prepared by subjecting the cells constituting the intestinal organoid formed in step (5) to plane culture in the presence of an epidermal growth factor and a TGF β receptor inhibitor. A highly functional evaluation system having the villi structure is constructed by using air-liquid interface culture in the plane culture.

Provided herein are methods of manufacturing β cells in vitro. Also provided herein are methods of treating a disease in a subject comprising administering the β cells manufactured in vitro to the subject. Also provided herein are methods of differentiating stem cells into β cells.

In related-art methods of differentiating pluripotent stem cells into a desired cell type, there has not been established a differentiation induction method using human ES/iPS cells and being stable and highly efficient. A method of inducing differentiation into a desired cell type within a short period of time and with high efficiency by attenuating differentiation resistance of a pluripotent stem cell to generate a pluripotent stem cell that actively proceeds to a differentiated cell type has been found, and thus the present invention has been completed.

Described herein is a growth medium for culture of stem cells and/or primary cells, in particular hematopoietic stem cells (HSCs), the growth medium including a basal medium and a supplement, with the medium and/or supplement including a histone acetyltransferase (HAT) inhibitor, a histone deacetylase (HDAC) inhibitor, and two or more of a lipid, an amino acid or amino acid derivative, an antioxidative agent, and an inorganic salt. Further provided are methods of using the growth medium, as well as kits and formulations of the growth medium.

The present invention relates to a method for ex vivo generating and expanding γδ Foxp3.sup.+ regulatory T cells, and therapeutic uses thereof. The inventors performed the induction of Foxp3+ expression in ex vivo human induced tumor-antigen specific CD4+ TCRγδ unrestricted T cells and the induction of autologous CD8-mediated T-cell responses against tumor-antigen specific FOXP3 expressing CD4+ TCRγδ unrestricted T cells. The inventors developed a method to ex vivo generated and expanded antigen specific Foxp3 expressing CD3+ TCRγδ+ unrestricted T cells, committed to exclusively exert regulatory activity, whichever culture condition of stimulation is. In particular, the present invention relates to a method for generating ex vivo γδ Foxp3+ regulatory T cells having the following phenotype: CD3+ TCRγδ+ Foxp3+.

The present invention relates to a method for ex vivo generating and expanding MHCII restricted CD4.sup.+ Foxp3.sup.+ regulatory T cells, and therapeutic uses thereof. The inventors here demonstrated the optimal conditions for inducing Foxp3 expression in naive CD3+ CD4+ TCRαβ+ MHCII restricted T following polyclonal or following antigen-specific activation. They also developed an experimental procedure to generate autologous CD8+ T cell lines functionally committed to lyse tumor-antigen specific FOXP3 expressing TCRαβ+ MHCII restricted T cells, pathogenic CD4+ T cells that favour tumor cell immune evasion. In particular, the present invention relates to a method for generating ex vivo MHCII restricted CD4+ Foxp3+ regulatory T cells having the following phenotype: CD3+ CD4+ Foxp3+.

Provided are compositions and methods comprising an epigenetic agent and a Wnt agonist for increasing proliferation of cochlear supporting cells or vestibular supporting cells, and related methods of treating inner ear hearing or balance disorders.

A population of enteroendocrine cells (EEC) is obtained from a mammalian post-natal cell population, such as a population including post-natal stem cells, by treating the population with a plurality of small molecules that upregulate ChgA and promote differentiation of the cells to form the enteroendocrine cells. The upregulation of ChgA is such that the fraction of cells expressing CGA in the obtained cell population, as measured by a ChgA Immunostaining Assay, is at least about 1.5%. Small molecules that can be used to differentiate the post-natal cells into the enteroendocrine cells can include at least one of a Wnt activator, a Notch inhibitor, a Wnt inhibitor, a MEK/ERK inhibitor, a growth factor, a HDAC inhibitor, a Histone Methylation Inhibitor, a Tgf-β inhibitor, and a NeuroD1 activator. Also, the insulin expression of a population of mammalian cells is increased by treating the population with a plurality of small molecules that increase the insulin expression.

An object of the present invention is to provide a method for preparing osteoblasts that are applicable, without causing risk of canceration, to bone defect repair or to the treatment of bone resorption, fracture, osteoporosis, or the like. To solve this problem, the present invention provides a method for preparing osteoblasts, the method comprising culturing mammal differentiated somatic cells in a medium in the presence of at least one compound selected from the group consisting of (1) statin compounds, (2) casein kinase 1 inhibitors, (3) cAMP inducers, and (4) histone methyltransferase inhibitors, to convert the somatic cells into osteoblasts.