Abstract: Provided herein include compositions, methods and systems for delivery of CRISPR/Cas-mediated gene editing systems using lipid nanoparticles (LNP) to trabecular meshwork cells. Methods, compositions and systems for treating glaucoma are also provided herein, which involve reducing the expression of myocilin (MYOC) gene in the trabecular meshwork cells of patients' eyes.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: Several embodiments of the methods and compositions disclosed herein relate to immune cells that are engineered to express chimeric antigen receptors (CAR) and/or genetically modified to reduce potential side effects of cellular immunotherapy. Several embodiments relate to genetic modifications to the immune cells, such as Natural Killer (NK) cells, to reduce, substantially, reduce, or eliminate expression of a combination of genes and their corresponding proteins. In several embodiments, one edit is to reduce expression of a marker by the immune cells that would otherwise cause them to be self-targeted by the CAR and at least two additional gene edits to enhance the cytotoxicity and/or persistence of the resulting cells. In several embodiments, the CAR targets CD70, and in some embodiments is used for renal cell carcinoma immunotherapy.

Abstract: Aspects of the present disclosure relate to compositions comprising a population of genetically engineered T cells that expresses a chimeric antigen receptor (CAR) that binds CD70, and methods of using such for the treatment of CD70+ solid tumors.

Abstract: High affinity antibodies capable of binding to a single-chain variable fragment (scFv) of anti-CD70 antibody, for example, the scFv expressed on cell surface as a portion of a chimeric antigen receptor (CAR). Also provided herein are methods for producing such anti-scFv antibodies and methods of using the antibodies disclosed herein for detecting, for example, T cells expressing an anti-CD70 CAR that comprise the scFv as an extracellular domain.

Abstract: Genetically engineered T cells expressing a chimeric antigen receptor (CAR) targeting CD19 and having multiple genetic edits, including a disrupted TRAC gene, a disrupted ?2M gene, a disrupted Regnase 1 gene, and/or a disrupted TGFBRII gene. Also provided herein are methods of making such genetically engineered T cells and methods of using the genetically engineered T cells in cancer treatment.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: Provided herein, in some embodiments, are methods and compositions (e.g., cell compositions) for the treatment of cancer.

Abstract: Methods for manufacturing genetically engineered T cells expressing a chimeric antigen receptor (CAR), such as a CAR that binds human CD19, BCMA, or CD70, and having multiple additional gene edits, for example, a disrupted Regnase-1 gene, a disrupted TGFBRII gene, a disrupted TRAC gene, a disrupted ?2M gene, or a combination thereof, using CRISPR/Cas gene editing systems.

Abstract: Aspects of the present disclosure relate to compositions comprising a population of genetically engineered T cells that expresses a chimeric antigen receptor (CAR) that binds CD70, and methods of using such for the treatment of T cell and B cell malignancies.

Abstract: Aspects of the present disclosure relate to compositions comprising a population of genetically engineered T cells that expresses a chimeric antigen receptor (CAR) that binds CD70, and methods of using such for the treatment of renal cell cancer (RCC).

Abstract: Aspects of the present disclosure relate to compositions comprising a population of genetically engineered T cells that expresses a chimeric antigen receptor (CAR) that binds CD70, and methods of using such for the treatment of T cell and B cell malignancies.

Abstract: A method for treating a solid tumor (e.g., a CD70+ solid tumor) comprising one or more cycles of treatment, each cycle comprising administering to a human patient in need thereof an effective amount of a population of genetically engineered T cells after a lymphodepleting therapy, and optionally a treatment comprising an anti-CD38 antibody. The population of genetically engineered T cells comprises T cells expressing a chimeric antigen receptor (CAR) that binds CD70.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: A population of genetically engineered T cells, comprising a disrupted Reg1 gene and/or a disrupted TGFBRII gene. Such genetically engineered T cells may comprise further genetic modifications, for example, a disrupted CD70 gene. The population of genetically engineered T cells exhibit one or more of (a) improved cell growth activity; (b) enhanced persistence; and (c) reduced T cell exhaustion, (d) enhanced cytotoxicity activity, (e) resistant to inhibitory effects induced by TGF-b, and (f) resistant to inhibitory effects by fibroblasts and/or inhibitory factors secreted thereby, as compared to non-engineered T cell counterparts.

Abstract: Provided herein, in some embodiments, are methods and compositions (e.g., cell compositions) for the treatment of cancer. The methods and compositions involve genetically engineered immune cells (e.g., T cells), in which the endogenous CD70 gene is disrupted by genetic editing, for example, the CRISPR/Cas9 gene editing technology.