Methods for generating human arterial endothelial cells under defined conditions in the absence of insulin are described. In particular, provided herein are efficient, defined, and scalable methods for generating human arterial endothelial cells from human pluripotent stem cells. Also provided herein are uses of human arterial endothelial cells obtained according to these methods. For example, methods of treating peripheral arterial disease and methods of screening agents for that effect adhesion of leukocytes to arterial endothelial cells are also provided.

A method for inducing differentiated cells into mesenchymal stem cells (MSCs), and combinations of regulatory targets thereof. The method includes performing a directional induction on the differentiated cells to prepare the mesenchymal stem cells. The directional induction includes treating cells by inhibiting the TGF-β signal pathway, inhibiting the activity of PKC, activating the WNT/β-catenin signal pathway and activating the cAMP signal pathway. By regulating corresponding signal pathways and/or enzymatic activities by stages, the differentiated cells are induced into the mesenchymal stem cells.

Provided herein are methods and compositions relating, in part, to the generation of human progenitor cells committed to the lung lineage and uses of such cells for treatment of lung diseases/disorders or injury to the lung. Whether an adult stem cell can be isolated from human adult lung remains controversial in the art and at present, methods for isolating and using adult lung stem cells from humans lack reproducibility. Thus, the methods and compositions described herein are advantageous over the present state of knowledge in the art and permit the generation of human lung progenitor cells for treatment, tissue engineering, and screening assays.

Provided herein are systems and methods for identifying cell-specific differentiation markers. In particular, provided herein are systems and methods for generating induced pluripotent cells (IPS) from human cells, differentiating the IPS into differentiated cells, and identifying differentiation specific markers.

A method for inducing differentiation into pancreatic α cells includes: a step (a) of culturing endodermal cells, which have been induced to differentiate from pluripotent stem cells, in the presence of a bone morphogenetic protein (BMP) signaling inhibitor, and retinoic acid or a retinoic acid analog to induce differentiation into primitive gut tube (PGT) cells; a step (b) of culturing the primitive gut tube (PGT) cells to induce differentiation into pancreatic endocrine precursor (EP) cells; and a step (c) of culturing the pancreatic endocrine precursor (EP) cells to induce differentiation into pancreatic α cells, in which the step (b) and the step (c) are performed in the absence of ascorbic acid.

Disclosed are engineered feeder cells comprising soluble or membrane bound TGF-b and methods of their use in the production of NK cells resistant to TGF-b and use of said generated TGF-b resistant NK cells to treat a cancer.

Methods for inducing human erythroid progenitor cells from hematopoietic stem cells are provided using chemically-defined culture media. Erythroid progenitors generated by the methods include megakaryocyte/erythroid progenitor cells (MEP cells) and CD71+CD235+CD34− erythroid cells, which can be further differentiated into red blood cells. Culture media, isolated cell populations and kits are also provided.

Compositions and methods are provided for induction and maintenance of quiescence of stem cells.

A method for making an at least double layered cell aggregate and/or an artificial blastocyst, and/or a further-developed blastoid termed blastoid, by forming a double layered cell aggregate from at least one trophoblast cell and at least one pluripotent and/or totipotent cell, and culturing the aggregate to obtain an artificial blastocyst having a trophectoderm-like tissue that surrounds a blastocoel and an inner cell mass-like tissue. The cell aggregate can be formed from toti- or pluripotent stem cell types, or induced pluripotent stem cell types, in combination with trophoblast stem cells. Formation of a blastoid can be achieved by culturing the cell aggregate in a medium preferably comprising one or more of a Rho/ROCK inhibitor, a Wnt pathway modulator, a PKA pathway modulator, a PKC pathway modulator, a MAPK pathway modulator, a STAT pathway modulator, an Akt pathway modulator, a Tgf pathway modulator and a Hippo pathway modulator. Also, a method for growing an at least double layered cell aggregate into an artificial blastocyst, and into a further-developed blastoid, a foetus or a live animal and an in vitro cell culture comprising the mentioned compounds and/or cell aggregates.

A human immature endocrine cell population and methods for making an immature endocrine cell population are provided. Specifically, immature beta cells and methods for production of immature beta cells are described. Immature beta cells co-express INS and NKX6.1 and are uni-potent and thereby develop into mature beta cells when implanted in vivo. The mature beta cells in vivo are capable of producing insulin in response to glucose stimulation.