The present invention relates to, inter alia, an engineered cell (e.g., iPSC, IPS-derived NK, or NK cell) comprising a disrupted B2M gene and an inserted polynucleotide encoding one or more of SERPINB9, a fusion of IL15 and IL15Rα, and/or HLA-E. The engineered cell can further comprise a disrupted CIITA gene and an inserted polynucleotide encoding a CAR, wherein the CAR can be an anti-BCMA CAR or an anti-CD30 CAR. The engineered cell may further comprise a disrupted ADAM17 gene, a disrupted FAS gene, a disrupted CISH gene, and/or a disrupted REGNASE-1 gene. Methods for producing the engineered cells are also provided, and therapeutic uses of the engineered cells are also described. Guide RNA sequences targeting described target sequences are also described.

Disclosed herein are compositions and methods to decellularize an isolated organ or portion thereof. Also disclosed herein are compositions and methods for treatment of disease utilizing a decellularized or recellularized organ. Also disclosed herein are methods of improving decellularization and/or recellularization of an isolated organ or portion thereof.

A method of direct transdifferentiation of somatic cells into other somatic cells may be convenient and still have good reproducibility, excellent production efficiency, and short performed time. Methods for direct transdifferentiation of somatic cells into other somatic cells may include: (a) introducing a GLIS family gene, a mutated GLIS family gene or a gene product thereof into somatic cells; and (b) culturing the gene-introduced somatic cells in a culture medium containing a component that induces differentiation of the somatic cells or precursor cells of the somatic cells into other somatic cells.

The present invention relates to a differentiation method for obtaining a large quantity of microglia by patterning, proliferating, culturing, and inducing the differentiation of yolk sac-mimic 3D organoids prepared from human pluripotent stem cells, wherein the microglia thus obtained in a large quantity exhibit significantly superior effects in terms of yield, purity, and storage stability compared to cells differentiated by existing differentiation methods, and thus may be utilized in research on lesions and therapeutic mechanisms of brain diseases, and drug screening platforms.

Provided herein are cells engineered to have improved protection against natural killer cell killing. The cells are engineered to comprise an insertion of a polynucleotide encoding SERPINB9. Also provided herein are methods of making the engineered cells and therapeutic uses of the engineered cells. The engineered cells can also comprise at least one genetic modification within or near at least one gene that encodes one or more MHC-I or MHC-II human leukocyte antigens or component or transcriptional regulator of the MHC-I or MHC-II complex, at least one genetic modification that increases the expression of at least one polynucleotide that encodes a tolerogenic factor, and optionally at least one genetic modification that increases or decreases the expression of at least one gene that encodes a survival factor. The engineered cells can be stem cells and the engineered stem cells can be differentiated into various lineages having protection against NK cell killing.

A mesenchymal stem cell culture product and a method for preparing the same are provided. The method for preparing the mesenchymal stem cell culture product includes the following steps. A predetermined quantity of mesenchymal stem cells is seeded in a flat culture device containing a first cell culture medium. When the mesenchymal stem cells proliferate to a target quantity, the first cell culture medium is replaced with a second cell culture medium, and the second cell culture medium is removed after incubation for 18 to 30 hours. A target cell culture medium is added and incubated for 48 to 72 hours. The target cell culture medium is collected repeatedly. The collected target cell culture medium is filtered and concentrated to obtain the mesenchymal stem cell culture product.

The invention provides culture platforms, cell media, and methods of differentiating pluriptent cells into hematopoietic cells. The invention further provides pluripotent stem cell-derived hematopoietic cells generated using the culture platforms and ethods disclosed herein, which enable feed-free, monolayer culturing and in the absence of EB formation. Specifically, pluripotent stem cell-derived hematopoietic cell of this invention include, and not limited to, iHSC, definitive hemogenic endothelium, hematopoietic multipotent progenitors, T cell progenitors, NK cell progenitors, T cells, and NK cells.

A pharmaceutical includes helper T cells induced from pluripotent stem cells. The helper T cells include CD4-positive CD40L-highly expressing T cells, dendritic cells, antigen, and cytotoxic T cells CD8-positive T cells. The pharmaceutical can be administered in a method for treating cancer to a patient having cancer cells expressing an antigen specifically recognized by CD4-positive T cells.

A method for producing a cell population containing cardiomyocytes, including (1) a step of bringing a histone deacetylase inhibitor into contact with a cell population containing cardiomyocytes and cells other than cardiomyocytes, the cell population being obtained by culturing pluripotent stem cells in a medium for cardiomyocyte differentiation, and (2) a step of culturing the cell population is provided by the present invention.

The present invention relates in part to nucleic acids encoding proteins, nucleic acids containing non-canonical nucleotides, therapeutics comprising nucleic acids, methods, kits, and devices for inducing cells to express proteins, methods, kits, and devices for transfecting, gene editing, and reprogramming cells, and cells, organisms, and therapeutics produced using these methods, kits, and devices. Methods for inducing cells to express proteins and for reprogramming and gene-editing cells using RNA are disclosed. Methods for producing cells from patient samples, cells produced using these methods, and therapeutics comprising cells produced using these methods are also disclosed.