Provided are methods of isolating pericyte progenitor cells from pluripotent stem cells such as embryonic stem cells and induced pluripotent stem cells, by isolating CD105+, CD73+ and/or CD105+/CD73+ cells from embryoid bodies and optionally by enriching the cells with CD31− cells. Also provided are methods of isolating endothelial cells and co-derivation of pericyte and endothelial cells progenitor cells from embryoid bodies, and methods of differentiating same for various therapeutic applications. In addition, the invention provides an isolated pericyte progenitor cell having an expression marker signature of CD105+/CD73+CD31−/alpha SMA−/CD133−/Flk-1−.

The present invention relates to the development and manufacturing of viral vaccines. In particular, the invention relates to the field of industrial production of viral vectors and vaccines, more in particular to the use of avian embryonic stem cells, preferably the EBx® cell line derived from duck embryonic stem cells, for the production of viral vectors and viruses. The invention is particularly useful for the industrial production of viral vaccines to prevent viral infection of humans and animals.

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.

The present invention relates in general to the field of recombinant protein expression. In particular, the present invention relates to a method for selecting a suitable candidate cell clone for recombinant protein expression and to a host cell for recombinant protein expression, the host cell exhibiting artificially modified gene expression of at least one gene selected from the group consisting of: Hist1h2bc, Egrl, BX842664.2/Hist 1h3c, Dhfr, Fgfr2, AC115880.11, Mmp10, Vsnll (optional), CU459186.17, El 30203 B14Rik, Cspg4, C1qtnf1, Foxp2, and Ptpre.

Disclosed herein are cell cultures comprising definitive endoderm cells and methods of producing the same. Also disclosed herein are cell populations comprising substantially purified definitive endoderm cells as well as methods for enriching, isolating and purifying definitive endoderm cells from other cell types.

The present invention relates to a pharmaceutical composition comprising of preparations of human embryonic stem (hES) cells and their derivatives and methods for their transplantation into the human body, wherein transplantation results in the clinical reversal of symptoms, cure, stabilization or arrest of degeneration of a wide variety of presently incurable and terminal medical conditions, diseases and disorders. The invention further relates to novel processes of preparing novel stem cell lines which are free of animal products, feeder cells, growth factors, leukaemia inhibitory factor, supplementary mineral combinations, amino acid supplements, vitamin supplements, fibroblast growth factor, membrane associated steel factor, soluble steel factor and conditioned media. This invention further relates to the isolation, culture, maintenance, expansion, differentiation, storage, and preservation of such stem cells.

The present disclosure provides methods and kits for the differentiation of stem cells into relevant liver cell lineages, as well as methods of using the relevant liver cell lineages in screening for a cellular response, a phenotype and in the treatment of a condition. In one embodiment, stem cells are first differentiated into cells of the definitive endoderm lineage, which are differentiated into posterior foregut (PFG) lineage cells by one or more of retinoic acid activators and/or one or more inhibitors of transforming growth factor-β (TGFβ). An additional embodiment provides a method for the differentiation of posterior foregut lineage cells into liver bud progenitors (LB) by one or more activators of TGFβ signalling, and/or one or more modulators of Wnt signalling, and/or one or more activators of cyclic AMP/PKA signaling; and a further embodiment provides a method for the differentiation of liver bud progenitors into hepatic progenitors by one or more inhibitors of TGFβ signalling and/or fibroblast growth factor (FGF) inhibitors and/or one or more Notch inhibitors. Another embodiment discloses the differentiation of hepatic progenitors into hepatocyte-like cells or perivenous hepatocyte-like cells by one or more of Notch inhibitors and/or activators of glucocorticoid signalling and/or one or more activators of insulin signalling and/or one or more of ascorbic acid signalling activators and/or additional factors. Methods and kits for maintaining LB in self renewal state, hepatocyte-like cells in perivenous or periportal state, as well as surface markers for LB and mid/hindgut (MHG) cells are also disclosed.

The invention described herein provides high throughput methods and reagents for generating transgenic animals (e.g., mammals) through introducing materials into gametes or preimplantation stage (e.g., one-cell embryo or zygotes) via electroporation, leading to genetically inheritable modification to the genome of the animal.

The present invention provides a method for proliferating neural progenitor cells and a composition for treating neurological diseases, the composition including a proliferated neural progenitor cell. When a fetal neural progenitor cell is cultured under a hypoxia condition and/or in a medium containing tocoperol, tocoperol acetate, or a mixture thereof, the improved cell proliferation rates of the fetal neural progenitor cell are confirmed. In addition, considering an effect of the neural progenitor cell on preventing differentiation thereof into neurons at the time of proliferation, the present disclosure may contribute to mass production of neural stem cells, and accordingly, the proliferated neural progenitor cell is expected to be utilized in the treatment of a neurological disease.

Novel fusion-circular RNAs (f-circRNAs) and complements thereof are provided. Diagnostic and treatment methods using f-circRNA inhibitors are provided. Non-human animals expressing exogenous f-circRNA and complements thereof are also provided.