According to the present disclosure, there is provided a method for manufacturing pluripotent stem cells including introducing a reprogramming factor into cells and seeding the cells, into which the reprogramming factor is introduced, at a low concentration and culturing the cells.

There is provided a quality improving agent for iPS cells, including a polynucleotide, in which the polynucleotide contains an H1foo gene and a regulatory sequence that is capable of regulating at least one of the amount and the period of existence of an H1foo protein expressed from the H1foo gene in cells when the H1foo gene is transduced into the cells.

The present disclosure relates to methods for transiently activating temperature-sensitive agents in one or more cells, for example by contacting one or more cells with a temperature-sensitive agent and transiently incubating the cells at a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. Additionally, the present disclosure relates to methods of contacting one or more cells in a subject with a temperature-sensitive agent and then lowering the subject's body temperature to a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. The disclosure also relates to methods of treating a subject with a temperature-sensitive therapeutic agent. In particular, the disclosure provides tools for temperature-sensitive delivery of ZSCAN4 nucleic acids and proteins to cells.

The present invention provides a method for preparing induced pluripotent stem cells through somatic cell reprogramming and induced pluripotent stem cells obtained therefrom. The present method comprises introducing the factors Oct4 and Nanog as reprogramming-inducing factors into somatic cells to perform reprogramming; followed by culturing the partially or fully reprogrammed somatic cells in a medium comprising specific chemical inducing agents to obtain induced pluripotent stem cells. In the present invention, the combination of different forms of reprogramming-inducing factors and three small-molecule compounds as chemical inducing agents can significantly improve the reprogramming efficiency of human somatic cells and reduce the tumorigenicity of the obtained induced pluripotent stem cells.

Cytotoxic T cells derived from human T cell-derived iPS cells may avoid an NK cell missing-self response and may be used for allogeneic administration while maintaining a strong antitumor effect of antigen-specific CTLs. A method may produce a cytotoxic T cell derived from a human T cell-derived iPS cell expressing HLA class I of HLA-restricted class I of an antigen epitope of a CTL and HLA-E. Such a method may include: knocking out all HLA class I of the human T cell-derived iPS cell; introducing a gene of the HLA-restricted HLA class I of the antigen epitope of the CTL and a gene of the HLA-E into the T-iPS cell in which all HLA class I have been knocked out; and redifferentiating the genetically introduced T-iPS cell into a CD8 single-positive T cell.

Simultaneous expression of a plurality of foreign genes by using a stealthy RNA gene expression system that is a complex that does not activate the innate immune mechanism and is formed from an RNA-dependent RNA polymerase, a single-strand RNA binding protein, and negative-sense single-strand RNAs including the following (1) to (8): (1) a target RNA sequence that codes for any protein or functional RNA; (2) an RNA sequence forming a noncoding region and derived from mRNA; (3) a transcription initiation signal sequence recognized by the RNA-dependent RNA polymerase; (4) a transcription termination signal sequence recognized by the polymerase; (5) an RNA sequence containing a replication origin recognized by the polymerase; (6) an RNA sequence that codes for the polymerase; (7) an RNA sequence that codes for a protein for regulating the activity of the polymerase; and (8) an RNA sequence that codes for the single-strand RNA binding protein.

The present disclosure relates to methods for transiently activating temperature-sensitive agents in one or more cells, for example by contacting one or more cells with a temperature-sensitive agent and transiently incubating the cells at a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. Additionally, the present disclosure relates to methods of contacting one or more cells in a subject with a temperature-sensitive agent and then lowering the subject's core body temperature to a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. The disclosure also relates to methods of contacting one or more cells in a subject with a temperature-sensitive agent, maintaining the subject's surface body temperature at a permissive temperature for inducing an activity of the temperature-sensitive agent in the cells. Further disclosed are methods of treating a subject with a temperature-sensitive therapeutic agent.

According to the present disclosure, there is provided a method for producing stem cells including: preparing somatic cells; preparing a chimeric virus including a virus-derived genomic RNA harboring an inducer RNA that induces somatic cells into stem cells and a virus-derived envelope surrounding the genomic RNA, wherein the genomic RNA and the envelope are derived from different viruses; and introducing the inducer RNA into the somatic cells using the chimeric virus.

Provided is a cell culture method including introducing a factor into cells in a cell culture vessel, and culturing the cells into which the factor has been introduced in the same cell culture vessel. Also provided is a mononuclear cell collection method including treating blood to prepare a treated blood from which erythrocytes have been at least partially removed, diluting the treated blood, causing sedimentation of mononuclear cells contained in the diluted treated blood, removing the supernatant from the diluted treated blood, and collecting the mononuclear cells.

The present invention relates to a vector(s) containing and expressing an optimized HIV EnvF gene, methods for making the same and cell substrates qualified for vaccine production which may comprise vector(s) containing optimized HIV genes.