There are provided to a Rag-2 (Recombination activating gene 2) gene targeting vector, a method for producing SCID-like miniature pigs introduced with the vector, and a use thereof.

A selection method of an iPS cell includes: at a reprogramming process to culture a cell including a plurality of combinations of initializing factors labelled with luminescent genes that are different with each other, acquiring a photon number per unit area or a photon number per unit time of each of the luminescent genes of the cell; judging whether the acquired photon number is more than a threshold that is predetermined for the acquired photon number; and when the acquired photon number is more than the threshold, selecting this cell as an objective cell for a next process.

A method of producing induced pluripotent stem cells including a step for introducing an initialization factor into somatic cells of a mammal, and culturing in a neural stem cell culture medium to obtain induced neural stem cell-like cells, and a step for cultivating said induced neural stem cell-like cells in a growth medium to obtain induced pluripotent stem cells, wherein the initialization factor contains an OCT family, a SOX family, a KLF family, a MYC family, a LIN28 family and a P53 function inhibitor.

The slow kinetics and low efficiency of reprogramming methods to generate human induced pluripotent stem cells (iPSCs) impose major limitations on their utility in biomedical applications. Here we describe a chemical approach that dramatically improves (>200 fold) the efficiency of iPSC generation from human fibroblasts, within seven days of treatment. This will provide a basis for developing safer, more efficient, non-viral methods for reprogramming human somatic 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 highly efficient. Many attempts have been made, including a stepwise differentiation induction method based on the control of culture conditions or the addition of, for example, various cell growth factors/differentiation factors to a culture solution, but the use of complicated culture steps is a big problem. A method of inducing differentiation into a desired cell type within a short period of time and with high efficiency by use of a pluripotent stem cell that actively undergoes cell differentiation, which is obtained by reducing an undifferentiated state of the pluripotent stem cell, has been developed, and thus the present invention has been completed.

The present disclosure provides compositions and methods of using gene therapy to create induced pluripotent stem cells (iPSCs) without inducing cancer or tumorigenesis. The methods disclosed herein employ plasmids and vectors that contain transcription factors and an anti-oncogene such as PCBP1 which inhibits the expression of cancer biomarkers and concomitant oncogenesis.

A method for coordinating the manufacturing of an expanded cell therapy product for a patient may include receiving a cell order request to expand the cell therapy product for the patient; generating a patient-specific identifier or cell order identifier associated with the cell order request; and initiating a process to expand the cell therapy product from at least some of a solid tumor obtained from the patient. If acceptance parameters for the expansion cell therapy product do not meet certain acceptance criteria at a second time point subsequent to a first time point in the expansion process, it is determined whether re-performing the expansion of the cell therapy product using the cell expansion technique is possible from the first time point based on the acceptance parameters at the second time point. If such re-performing the expansion is possible, patient treatment events that use the expanded cell therapy product are rescheduled.

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. The use of complicated culture steps is a large problem. In addition, there are also large problems in, for example, that the speed of cell differentiation is low, and hence long-period culture is required, and that the differentiation efficiency is low, and hence it is difficult to obtain a sufficient number of required cells. A method of inducing differentiation into a desired cell type, which induces differentiation within a short period of time and with high efficiency by the use of a Sendai virus vector capable of expressing a transcription factor, and as required, the use of a pluripotent stem cell in which an expression amount of a POU5F1 protein has been substantially removed or reduced, is provided.

Provided here in are methods of producing induced pluripotent stem cells (iPSCs) and isolated population of produced induced pluripotent stem cells (iPSCs). Also provided herein are methods of treating a subject in need thereof using the produced iPSCs or pharmaceutical compositions comprising the produced iPSCs.

The present invention pertains to a method for producing induced pluripotent stem cells, and more specifically, to a method for producing induced pluripotent stem cells using RNA nanoparticles for cell transformation, wherein: cell transformation can be effectively performed without genetic modification by producing induced pluripotent stem cells using self-assembled RNA nanoparticles including at least one RNA selected from the group consisting of messenger RNA for expressing transcription factors which induce somatic cells and adult stem cells to be dedifferentiated into induced pluripotent stem cells, micro RNA facilitating the dedifferentiation process, and small interfering RNA; the production efficiency of iPSCs can be maximized by adjusting structural properties and activity; and low gene loading efficiency can be overcome by applying an infinite replication process to incorporate high concentrations of RNA in RNA nanoparticles.