The present disclosure provides methods and compositions for enhancing the immune response toward cancers and pathogens. It relates to chimeric antigen receptors (CARs) comprising a mutated CD28 intracellular motif, and cells comprising such CARs. The presently disclosed subject matter further relates to the use of said cells for treating diseases, e.g., for treating cancers.

The invention relates to mesodermal killer (MK) cells and their use in therapy, especially for the treatment of cancer.

The present invention discloses an in-vitro culture, induction, activation and cryopreservation method and cell bank establishment for immune cells. The method includes the follows: using a dedicated amplification medium of immune cells to perform first-stage amplification culture on mononuclear cells to obtain preliminarily amplified immune cells; using a dedicated induction medium of immune cells to perform second-stage induction and amplification culture on the preliminarily amplified immune cells to obtain induced immune cells; using a dedicated activation medium of immune cells to perform third-stage activation and amplification culture on the induced immune cells to obtain a large number of immune cells with activation functions; using a dedicated cryopreserving fluid of immune cells to cryopreserve the immune cells to obtain cryopreserved immune cells; and performing preservation according to ABO/RH typing and HLA typing; and establishing an information file of immune cells for retrieval to construct an immune cell bank.

Methods of culturing embryonic stem cells, induced pluripotent stem cells and/or differentiated cells in culture medium comprising activin are described. In one aspect, the disclosure features a pluripotent human stem cell, wherein the stem cell comprises: (i) a genomic edit that results in loss of function of Cytokine Inducible SH2 Containing Protein (CISH) and (ii) a genomic edit that results in a loss of function of an agonist of the TGF beta signaling pathway, or a genomic edit that results in a loss of function of adenosine Ata receptor.

This disclosure describes genetically engineered natural killer (NK) cells, pharmaceutical compositions that include these NK cells, and methods of making and using these NK cells.

The present disclosure provides compositions and methods for cell transplantation therapy based on forced expression of an exogenous HLA-F protein in donor cells to be transplanted into a subject. In some embodiments, the donor cells express an exogenous chimeric HLA-F protein comprising an extracellular region comprising an HLA-F alpha 1 domain, an HLA alpha 2 domain, an HLA-F alpha 3 domain, a linker and a β2m protein.

The present invention relates to the field of immunology, molecular biology and therapeutics. In particular, the invention relates to novel artificial feeder cells for activation and expansion of natural killer (NK) cells. The artificial feeder cell expresses endogenous ligands (HLA C1, C2, 5 and Bw4 type) for killer cell immunoglobulin-like receptors (KIRs), non-KIR binding Bw6 ligand, endogenous HLA-E-ligand for inhibitory NKG2A receptor, and comprises at least one stimulatory cytokine either membrane bound or secreted or at least one co-stimulatory ligand where those ligands and cytokines each specifically bind to a cognate receptor on a NK cell of interest, thereby mediating expansion of the NK cell. The invention can be used as an “off the 10 shelf” artificial feeder cell that can be readily designed to expand a NK cell or a NK subset of interest and also specifically expand NK cells modified with a chimeric antigen receptor (CAR). By genetically introducing or knockdown of candidate genes, the artificial feeder cell of the invention can be used to identify the stimulatory, co-stimulatory, and any other factors that mediate growth, expansion and cytotoxicity of a NK cell. Thus, the present invention provides 15 powerful tools for development of novel therapeutics where activation and expansion of the NK cell and of the CAR-NK cell can provide a benefit.

Embodiments of the disclosure encompass improvements on cell therapies by allowing the cells to be more effective for cancer treatment, including in a solid tumor microenvironment. In specific cases, the cells are modified to have reduced or inhibited levels of expression of T-Cell Death Associated Gene 8 (TDAG8), such as by CRISPR gene editing. In specific cases, the cells are further modified to express, for example, one or more engineered receptors, one or more cytokines, and optionally a suicide gene.

A multispecific nanobodies chimeric antigen receptor and T-cell engager includes an HLA-G nanobody chimeric antigen receptor and a bispecific T-cell engager. The HLA-G nanobody chimeric antigen receptor includes an HLA-G nanobodies unit, a transmembrane domain, and a CD3z signaling domain. The bispecific T-cell engager includes a PD-L1 nanobodies unit and a CD3e nanobody.

The present disclosure provides methods and compositions for genetically modifying lymphocytes, for example T cells and/or NK cells. In some embodiments, the methods include reaction mixtures, and resulting cell formulations, that are created using whole blood, or a component thereof that is not a PBMC, and additionally comprise T cells and recombinant retroviral particles having polynucleotides that encode a CAR. In some embodiments, modified lymphocytes are reintroduced into a subject subcutaneously. In some embodiments, polynucleotides that provide T cells the ability to regulate cell survival and proliferation in response to binding to a CAR, are provided.