Provided is a method for inducing T cells for a cell-based immunotherapy, comprising the steps of: (1) providing Rag 1 and/or Rag 2 gene knockout human pluripotent stem cells bearing genes encoding a T cell receptor specific for a desired antigen, and (2) inducing T cells from the pluripotent stem cells of step (1). Further provided are a cell-based immunotherapy method that uses the T cells for the cell-based immunotherapy and an iPS cell bank for the cell-based immunotherapy.

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 invention describes a method for increasing transfection efficiency of cells. The present invention further provides a method for increasing the efficiency of stem cell reprogramming.

Aspects of the present invention are drawn to compositions of somatic cells with innate potential for pluripotency (SCIPP). SCIPP have the capacity to differentiate into functional derivatives of each of the major germ layers (i.e., ectodermal, endodermal and mesodermal). Also provided are methods and kits for identifying and isolating the somatic cells from a subject as well as for employing SCIPP for research or therapeutic purposes.

Methods for generating thymic epithelial progenitor (TEP) cells from pluripotent stem (PS) cells in vitro are provided. Compositions and systems of cell populations of TEP cells as well as cells formed during different stages of differentiation of PS cells into TEP cells are also disclosed. The methods, isolated in vitro cell populations, compositions, and systems disclosed provide functional TEP cells that mature into thymic epithelial cells in vivo.

A method of generating protein-induced pluripotent stem cells by delivering bacterially expressed reprogramming proteins into nuclei of starting somatic cells using the QQ-protein transduction technique, repeating several cell reprogramming cycles for creating reprogrammed protein-induced pluripotent stem cells, moving the reprogrammed cells into a feeder-free medium for expansion, and expanding and passaging the reprogrammed cells in a whole dish for generating homogeneous piPS cells. Also provided are the piPCS cells formed using this method and uses thereof.

Disclosed are methods of detecting abnormal expression of one or more genes associated with a neurological disease such as the Alexander disease, the Alzheimer's disease, the Parkinson disease, the Huntington disease, multiple sclerosis, and amyotrophic lateral sclerosis. The methods include performing a transcriptome analysis of the astrocytes derived from a patient and the astrocytes derived from a healthy control subject, thereby to determine one or more genes that are substantially differentially expressed. Also disclosed are methods of treating a neurological disease by correcting the abnormally expressed genes associated with the neurological disease.

Methods and compositions for rapid development of reporter lines utilizing safe harbor sites in iPSCS, as well as other progenitor cells, pluripotent and multipotent stem cells and differentiated cells, and multiple Lox sites are provided.

Provided are age-modified cells and method for making age modified cells by reducing or increasing the level of genomic nucleic acid methylation in the cells. The aging and/or maturation process can be accelerated or reduced and controlled for young, aged, mature and/or immature cells, such as a somatic cell, a stem cell, a stem cell-derived somatic cell, including an induced pluripotent stem cell-derived cell, by reducing or increasing the level of genomic nucleic acid methylation in the cells. Methods described by the present disclosure can produce age-appropriate cells from a somatic cell or a stem cell, such as an old cell, young cell, immature cell, and/or a mature cell. Such age-modified cells constitute model systems for the study of late-onset diseases and/or disorders.

A bottom surface of a container (1) formed of a flexible material is partially raised to be partitioned it into plural compartments (10), and cells are cultured in each compartment (10). In due time, the compartments (10) are removed to expand a culture area in the container. As a result, the cell density at the time of culture can be maintained at an appropriate level, and an operation of transferring cells from one culture container to another culture container at the time of proliferating cells in a large amount can be eliminated, whereby damage on cells and risk of contamination can be reduced.