The present invention relates to compositions and methods for generating a modified T cell with a nucleic acid capable of downregulating endogenous gene expression selected from the group consisting of TCR α chain, TCR β chain, beta-2 microglobulin and FAS further comprising a nucleic acid encoding a modified T cell receptor (TCR) comprising affinity for a surface antigen on a target cell or an electroporated nucleic acid encoding a chimeric antigen receptor (CAR). Also included are methods and pharmaceutical compositions comprising the modified T cell for adoptive therapy and treating a condition, such as an autoimmune disease.

The present invention relates to compositions and methods for generating a modified T cell with a nucleic acid capable of downregulating endogenous gene expression selected from the group consisting of TCR α chain, TCR β chain, beta-2 microglobulin and FAS further comprising a nucleic acid encoding a modified T cell receptor (TCR) comprising affinity for a surface antigen on a target cell or an electroporated nucleic acid encoding a chimeric antigen receptor (CAR). Also included are methods and pharmaceutical compositions comprising the modified T cell for adoptive therapy and treating a condition, such as an autoimmune disease.

A method of manipulating allogeneic cells for use in allogeneic cell therapy providing a composition of highly activated allogeneic T-cells which are infused into immunocompetent cancer patients to elicit a novel anti-tumor immune mechanism, or “Mirror Effect”. In contrast to current allogeneic cell therapy protocols where T-cells in the graft mediate the beneficial graft vs. tumor (GVT) and detrimental graft vs. host (GVH) effects, the allogeneic cells of the present invention stimulate host T-cells to mediate the “mirror” of these effects. The mirror of the GVT effect is the host vs. tumor (HVT) effect. The “mirror” of the GVH effect is the host vs. graft (HVG) effect The anti-tumor HVT effect occurs in conjunction with a non-toxic HVG rejection effect. The highly activated allogeneic cells of the invention can be used to stimulate host immunity in a complete HLA mis-matched setting in a patient.

Disclosed herein are conditioning regimens and methods for inducing MHC- or HLA-mismatched mixed chimerism by conditioning a recipient with radiation-free, low-doses of cyclophosphamide (CY), pentostatin (PT), and anti-thymocyte globulin (ATG) prior to transplantation of donor bone marrow cells. In certain embodiments, the donor bone marrow cells may be CD4+ T-depleted bone marrow cells. The conditioning regimens and methods may also include administering one or more populations of conditioning donor cells selected from donor CD4.sup.+ T-depleted spleen cells, donor CD8.sup.+ T cells, and donor G-CSF-mobilized peripheral blood mononuclear cells. The conditioning regimen is clinically acceptable and can be used for treating hereditary hematological diseases and autoimmune diseases, as well as for promoting organ transplantation immune tolerance.

Disclosed herein are conditioning regimens and methods for inducing MHC- or HLA-mismatched mixed chimerism by conditioning a recipient with radiation-free, low-doses of cyclophosphamide (CY), pentostatin (PT), and anti-thymocyte globulin (ATG) prior to transplantation of donor bone marrow cells. In certain embodiments, the donor bone marrow cells may be CD4+ T-depleted bone marrow cells. The conditioning regimens and methods may also include administering one or more populations of conditioning donor cells selected from donor CD4.sup.+ T-depleted spleen cells, donor CD8.sup.+ T cells, and donor G-CSF-mobilized peripheral blood mononuclear cells. The conditioning regimen is clinically acceptable and can be used for treating hereditary hematological diseases and autoimmune diseases, as well as for promoting organ transplantation immune tolerance.

Methods of producing human stem cells are disclosed for parthenogenetically activating human oocytes by manipulation of O.sub.2 tension, including manipulation of Ca.sup.2+ under high O.sub.2 tension and contacting oocytes with serine threonine kinase inhibitors under low O.sub.2 tension, isolating inner cell masses (ICMs) from the activated oocytes, and culturing the cells of the isolated ICMs under high O.sub.2 tension. Moreover, methods are described for the production of stems cells from activated oocytes in the absence of non-human animal products, including the use of human feeder cells/products for culturing ICM/stem cells. Stem cells produced by the disclosed methods are also described.

Methods of producing human stem cells are disclosed for parthenogenetically activating human oocytes by manipulation of O.sub.2 tension, including manipulation of Ca.sup.2+ under high O.sub.2 tension and contacting oocytes with serine threonine kinase inhibitors under low O.sub.2 tension, isolating inner cell masses (ICMs) from the activated oocytes, and culturing the cells of the isolated ICMs under high O.sub.2 tension. Moreover, methods are described for the production of stems cells from activated oocytes in the absence of non-human animal products, including the use of human feeder cells/products for culturing ICM/stem cells. Stem cells produced by the disclosed methods are also described.

Methods and compositions for modifying T-cells in which PD1 and/or CTLA-4 is repressed and/or inactivated using fusion proteins such as artificial transcription factors and nucleases.

Methods and compositions for modifying T-cells in which PD1 and/or CTLA-4 is repressed and/or inactivated using fusion proteins such as artificial transcription factors and nucleases.

Genetically modified cells, tissues, and organs for treating or preventing diseases are disclosed. Also disclosed are methods of making the genetically modified cells and non-human animals.